Method and apparatus for communications over low bandwidth communications networks

ABSTRACT

A system having a distributed web site is described. The web site is distributed between a client, a server and a web server. The client stores a set of predefined applications that correspond to a part of the web site. The applications are formatted according to a first markup language. From the set of predefined applications, the client can generate queries. The server receives the queries and generates new, related queries. The new queries correspond to a second query protocol. The second query protocol is used by the web server. The web server generates responses to the new queries and sends these responses to the server. The responses are formatted according to a second markup language. These responses correspond to the second portion of the web site. The server then converts the responses into new responses that the client can use.

CROSS REFERENCE TO RELATED APPLICATIONS

This application is a divisional of application Ser. No. 11/119,209, entitled “METHOD AND APPARATUS FOR COMMUNICATING INFORMATION OVER LOW BANDWIDTH COMMUNICATIONS NETWORKS,” filed Apr. 29, 2005, now U.S. Pat. RE43247, which is a divisional of application Ser. No. 10/767,957, entitled “METHOD AND APPARATUS FOR COMMUNICATING INFORMATION OVER LOW BANDWIDTH COMMUNICATIONS NETWORKS,” filed Jan. 29, 2004, now U.S. Pat. RE40459, which is a reissue application of U.S. Pat. No. 6,343,318, all assigned to the assignee of the present application. The subject matter in the above-identified and commonly owned application(s) is incorporated herein by reference.

U.S. patent application Ser. No. 09/087,515, entitled “Method and Apparatus for Communicating Information over Low Bandwidth Communications Networks,” filed May 29, 1998, having inventors Jeffrey C. Hawkins, Joseph K. Sipher and Scott D. Lincke.

U.S. patent application Ser. No. 09/087,563, entitled “Method, System and Apparatus for Packet Minimized Communications,” filed May 29, 1998, having inventors Ronald Marianetti II, Scott D. Lincke, and Jeffrey C. Hawkins.

U.S. patent application Ser. No. 09/086,888, entitled “Method and System for Secure Communications,” filed May 29, 1998, having inventors Ronald Marianetti II and Scott D. Lincke, now U.S. Pat. No. 6,253,326.

U.S. patent application Ser. No. 09/087,552, entitled “Method and System for Wireless Internet Access,” filed May 29, 1998, having inventor Jeffrey C. Hawkins.

COPYRIGHT NOTICE

A portion of the disclosure of this patent document contains material that is subject to copyright protection. The copyright owner has no objection to the facsimile reproduction by anyone of the patent disclosures, as it appears in the Patent and Trademark Office patent files or records, but otherwise reserves all copyright rights whatsoever.

FIELD OF THE INVENTION

This invention relates to the field of information communications. In particular, the invention relates to low bandwidth network access to Internet based information.

BACKGROUND OF THE INVENTION

Wireless communications provides one method for mobile users to communicate to a wired network. In particular, wireless communications allows consumers to receive and send information. Examples of such wireless networks include cellular phones, pager systems, and satellite systems. The wireless network systems can be broken into relatively high bandwidth and low bandwidth systems. High bandwidth systems are for example satellite systems. Lower bandwidth systems include cellular phones and mobile radio systems. Still lower bandwidth systems include pager networks and low bandwidth packet switched radio systems (e.g., the BellSouth Mobile Data Mobitex™ system).

For users to access information on the Internet using wireless communications, the method in which they access the information is highly dependent on the type of wireless communications available to the user. For example on a high bandwidth network such as a wired network or a satellite system, usual techniques for browsing data on the Internet are adequate.

An important source of Internet based data is the data accessible through the World Wide Web (referred to as the Web). The following describes the usual techniques for Web browsing. A user selects a web site associated with a URL (Uniform Resource Locator). The URL represents the address of the entry point to the web site (e.g., the home page for the web site). For example, the user may select a web site that supplies restaurant reviews. The user's computer (the client) makes an HTTP (HyperText Transport Protocol) request to the web server hosting the web site. The client typically needs to make multiple HTTP requests of the web server. For example, to load the restaurant locator home page, multiple HTTP requests are needed to download all the graphics, frame content, etc. Next, the user will typically need to browse through a number of linked pages to get to the page from which a search for restaurants can be made. Even if the user is immediately presented with the desired page, a great deal of information has had to been downloaded from the web site (e.g., graphics, advertisements, etc.). This additional information makes for a visually rich browsing experience. The user fills in the information on this page and selects a search button. The client makes another series of HTTP requests of the web server. The web server supplies the client with the requested information in an HTML formatted web page. The web page typically includes links to more graphics and advertisements that need to be accessed by the client.

For low bandwidth networks this technique does not work well. Too much bandwidth is needed to download the images. Also, low bandwidth networks typically charge per byte transmitted and can be very expensive if large amounts of data are downloaded. Thus, low bandwidth networks are desirable to use for accessing information on the Web but only if the amount of data transferred over the network is small. Specifically for packet data networks, the cost of transmitting messages increases with the number of packets transmitted. The cost of transmitting multiple packet messages is therefore a formidable obstacle for packet data network customer use.

One area in which Web access is becoming more desirable is in handheld devices. Handheld devices are emerging as important computer devices. Handheld devices typically implement a relatively small, but important function set. Examples of such handheld devices are the PalmPilot™ handheld device available from 3COM Corporation, Inc. of Santa Clara, Calif. Examples of the function set supported are address books, calendars, and task lists.

In the past, wireless communications with handheld devices have been performed using wireless modems, such as are available from Novatel Communications, Inc. of Calgary, Alberta, or wireless transceivers for dedicated wireless data access network. Essentially a wireless modem operates in the cellular phone network and supplies approximately 9600 baud bandwidth to the handheld device. This allows the user to access the web at a relatively low bandwidth.

An issue with using handheld devices to access the Web is related to their capabilities. Even if connected to a high bandwidth network, most handheld devices do not have the screen area or the processing power to display the graphics and large amounts of text in a typical web page. However, it is still desirable to support the browsing of information on the Web using handheld devices. It is further desirable that the handheld devices be able to use networks that have relatively low bandwidths.

Some of the methods by which previous systems addressed some of the issues described above are now described.

One method of reducing the amount of data transferred from the web site to the client is to cache the web site data locally on the client. For example, the Netscape Communicator™. browser application caches web pages on the client. Each cached web page is associated with a URL. Thus, when the client requests a web page, the Netscape Communicator browser attempts to use previously cached web pages before downloading the pages from the web site. Another type of caching program is NetAttache™, available from Tympany, Inc. of Mountain View, Calif. The NetAttache program downloads all the web pages from a given web site. The web pages are all cached on the client. A NetAttache server runs locally on the client. A browser can then be used to browse through the local copy of the web pages. The problem caching is that the pages still need to be retrieved from the server before they can be reused and there can still be a significant number of connections made to the web server.

Alternatively, some programs are customized for accessing specific information from particular web sites. Examples of these programs are Java applets that reside on the client or are served to the client by a server. The applets can then be reused to access information from a web site. An example of a specialized program for accessing specific information is the RealVideo Player from Real Networks, Inc. A problem with these types of programs is that they are very specific to a particular type of content. For example, they do not use standard HTML (hypertext markup language) constructs. This means that web site developers cannot use standard web site development tools to create their sites.

Therefore what is desired is an improved system and method for handheld device to access Internet information over relative low bandwidth networks.

SUMMARY OF THE INVENTION

The following summarizes various embodiments of the invention.

One embodiment of the invention includes a system having a distributed web site. The web site is distributed between a client, a server and a web server. The client stores a set of predefined applications that correspond to a part of the web site. The applications include data formatted according to a first markup language. From the set of predefined applications, the client can generate queries. The server receives the queries and generates new, related queries. The new queries correspond to a second query protocol. The second query protocol is used by the web server. The web server generates responses to the new queries and sends these responses to the server. The responses are formatted according to a second markup language. These responses correspond to the second portion of the web site. The server then converts the responses into new responses that the client can use.

In some embodiments, the client includes a handheld computer that has wireless communications capabilities at least a part of the communications between the client and the server is done wirelessly.

In some embodiments, the client includes a browser application that interfaces with the applications in the set of applications. To execute an application in the set of applications, the browser application is also executed. The browser application is responsible for rendering the data in the first markup language, initiating queries, and rendering responses.

In some embodiments, the data in the applications correspond to a number of hyper-linked markup pages. At least some of the hyper-linked markup pages include data for generating the query. The hyper-linked markup pages correspond to a part of a web tree. Each of the applications can therefore correspond to a part of a corresponding web tree of a corresponding web site being served by a corresponding web server.

In some embodiments, the client includes additional applications. These additional applications can include data formatted according to the first markup language and/or they can be stand alone applications that otherwise interface with the browser application to generate queries.

In some embodiments, the second markup language is HTML (HyperText Markup Language) and the first markup language is a compressed version of at least part of HTML.

In some embodiments, the queries from the client to the server are sent according to a first protocol. The queries from the server to the web server are sent according to a second protocol. In some embodiments, the second protocol includes HTTP (HyperText Transport Protocol) and the first protocol corresponds to a compressed version of HTTP.

Although many details have been included in the description and the figures, the invention is defined by the scope of the claims. Only limitations found in those claims apply to the invention.

BRIEF DESCRIPTION OF THE DRAWINGS

The figures illustrate the invention by way of example, and not limitation. Like references indicate similar elements.

FIG. 1 illustrates a wireless communications device communicating with a web server.

FIG. 2 illustrates a method of communicating between a wireless communications device and a web server.

FIG. 3 illustrates an example user interface for a wireless communications device.

FIG. 4 illustrates a wireless network topology.

FIG. 5 illustrates a wireless network topology including a wireless network interface, a wireless network leased line, and a dispatcher.

FIG. 6 illustrates an example of a wireless communications device exchanging messages in a communications system.

FIG. 7 illustrates a reliable message protocol packet structure.

FIG. 8 illustrates an exchange of a single request packet and a single response packet using the reliable message protocol.

FIG. 9 illustrates an exchange of messages comprising a single request packet and two response packets using the reliable message protocol.

FIG. 10 illustrates an exchange of messages including a retransmit sequence using the reliable message protocol.

FIG. 11 illustrates lower level communication layers.

FIG. 12 illustrates the format of data passed between wireless client software layers.

FIG. 13 illustrates the format of an IP header and a UDP header.

FIG. 14 illustrates an alternative system for communicating between a wireless communications device and a web server.

DETAILED DESCRIPTION OF THE INVENTION Overview

This overview section generally describes some of the more important features of various embodiments and then briefly reviews the material in the subsequent sections.

A significant challenge in creating a wireless information solution for handheld devices is providing a product that is both useful and practical given the severely limited bandwidth and high power requirements of a wireless radio. Hardware and software should be optimized to conserve battery power and to reduce the amount of traffic that is sent over the wireless link. The wireless communications device, of various embodiments of the invention, has programs for web access and two-way messaging. One of these programs can include most of the static data from a web site. The static data can be used to format a query to access the dynamic data from the web site. Each program can be for accessing a different web site. Importantly, only the amount of static data that is communicated is significantly reduced.

The wireless communications device communicates as part of a communications system. The communications system includes the wireless communications device, a server, and a source of data. The server acts as a proxy server. Typical sources of data are a web server or a mail server.

Some wireless networks, such as those provided for two-way pagers and other wireless packet data networks, provide wider coverage and lower cost than competing networks. These wireless networks typically have relatively low performance however. A single packet of 400 bytes can take eight seconds just to travel to the Internet and back when the system is lightly loaded. With such a low throughput, it could easily take minutes to download even a small web page using standard browser technology. The wireless communications system therefore employs novel methods for reducing the amount of traffic sent over the wireless link for web access.

A goal of the invention is to provide the user with fast access to web content. Although the wireless communications device can access generic web content, because of the wireless communications device's limited screen size, most existing content will not be as visually appealing, will be harder to navigate, and may take longer to access than specially formatted content. Thus, significantly advantages are achieved with customized content. The web content can be formatted for the small screens of most handheld communications devices. This content will download relatively quickly (because of its small size). The formatted content can be created and published using the same tools used today for desktop web publishing (i.e. HTML tools and web servers) and could even be viewed using a standard desktop browser.

A second goal of the invention is wireless messaging. To help achieve this goal, a proxy server facilitates communications between web servers, mail servers, and other Internet data sources and the wireless communications device. The proxy server improves performance for wireless networks. Because of the high latency and low bandwidth of wireless networks, using existing Internet protocols to directly access web servers from the wireless communications device would be prohibitively expensive and slow.

Another important factor to consider with wireless networks is latency. A minimum size packet has a round trip time of approximately three seconds on the low cost wireless network. Because of the large latency, the number of packets sent over the wireless link between the wireless communications device and the proxy server should generally be kept small. Thus, some embodiments of the invention are able to fetch most web pages and send or receive messages with just one packet up (wireless client→proxy server) and one packet down (proxy server→wireless client) over the wireless network.

Thus, some of the more important features of various embodiments of the invention have been described. The following provides an overview of the sections in the detailed description.

The Definitions section provides definitions of terms used in the detailed description.

The System Introduction section provides an introduction to the various elements of the wireless communications system.

The Wireless Network Topology section introduces the protocols used to communicate between the various devices in the system.

The Content Layer section describes the markup languages used in the system.

The Transfer Layer section describes a compact transfer protocol (CTP) used for communicating between the wireless communications device and the proxy server.

The Reliable Message Protocol section describes reliable and efficient variable length message delivery over the wireline and wireless networks.

The Wireless Network Interface section describes a set of programs that can be used to access the wireless network as an IP network.

The Proxy Server Details section describes how the proxy server works with the content layer, the transfer layer, and the reliable message protocol.

The Communications System Details section describes how the content layer, the transfer layer, the reliable message protocol, the network interface and the proxy server can be used together.

Definitions

The following definitions will be helpful in understanding the description.

Computer—is any computing device (e.g., PC compatible computer, Unix workstation, handheld device etc.). Generally, a computer includes a processor and a memory. A computer can include a network of computers.

Handheld Device (or Palmtop Computer)—a computer with a smaller form factor than a desktop computer or a laptop computer. Examples of a handheld device include the Palm III™ handheld computer and Microsoft's palm sized computers.

User—any end user who would normally wish to retrieve information from the World Wide Web.

Internet—is a collection of information stored in computers physically located throughout the world. Much of the information on the Internet is organized onto electronic pages. Users typically bring one page to their computer screen, discover its contents, and have the option of bringing more pages of information.

Client—a computer used by the user to make a query.

Server—a computer that supplies information in response to a query, or performs intermediary tasks between a client and another server.

World Wide Web (or Web or web)—is one aspect of the Internet that supports client and server computers handling multimedia pages. Clients typically use software, such as the Netscape Communicator® browser, to view pages. Server computers use server software to maintain pages for clients to access.

Program—a sequence of instructions that can be executed by a computer. A program can include other programs. A program can include only one instruction.

Application—is a program or a set of hyper-linked documents.

System Introduction

FIG. 1 illustrates a wireless communications device communicating with a web server. In this example, the wireless communications device includes a handheld computer (or portable computer) having wireless communications capabilities. The handheld computer has predefined applications that correspond to a portion of the web site being served by the web server. Using the applications, a user can use to make queries of the web server. Some embodiments of the invention provide compression techniques that enable the wireless handheld computer to complete a web based information request using only one packet up to a proxy server and only one packet back down to the wireless communications device.

The following paragraphs first list the elements of FIG. 1, then describe how the elements are coupled, and then describe the elements in detail. FIG. 2 describes the operation of the elements.

This paragraph lists the elements of FIG. 1. FIG. 1 includes a wireless communications device 100, a base station 170, a proxy server 180, the Internet 190, and a web server 140. The wireless communications device 100 includes a screen 101 and is running an operating system 102. The operating system supports the execution of a browser 104. The browser 104 runs with the wireless application 106 and displays an example query form 105 and an example query response 107. Between the base station 170 and the proxy server 180 is a private network 172. The web server 140 includes a CGI (Common Gateway Interface) program 142. The CGI program 142 is responsible for generating the HTML page 144. FIG. 1 also includes a number of arrows indicating queries and responses. These queries and responses include a wireless CTP (Compressed Transport Protocol) query 122, a CTP query 124, an HTTP query 126, an HTTP response 136, a CTP response 134, and a wireless CTP response 132.

The following describes how the elements of FIG. 1 are coupled. The wireless communications device 100 communicates with the base station 170 via wireless communications. The base station 170 is coupled to the proxy server 180 via the private network 172. The proxy server 180, and the web server 140 are all coupled to the Internet 190.

The following paragraphs describe the elements of FIG. 1 in greater detail.

The wireless communications device 100 represents a handheld device that has wireless communications capabilities (also referred to as a portable computer or handheld computer with wireless communications capabilities). In one example system, the wireless communications device 100 includes a Palm III™ compatible handheld device having wireless communications capabilities. The wireless communications device 100 is for communicating over the BellSouth Mobile Data (BSMD) Mobitex system. Other embodiments of the invention support other wireless communications networks. Importantly, the BSMD Mobitex system is a relatively low bandwidth network. The embodiments of the inventions support querying of web based data using such a low bandwidth network.

The operating system 102 is an example of an operating system that can run on a handheld computer. Examples of such operating systems include the Palm OS™ operating system, available from the 3COM Corporation, of Santa Clara, Calif. The operating system 102 supports the running of applications. The operating system 102 also supports low level communications protocols, user interface displays, and user input.

The browser 104 is an example of a program (or group of programs) that supports some standard browsing features (e.g., displaying markup language documents, following hyper-links). The browser 104 is for generating queries and receiving responses. The browser 104 can interface with groups of hyper-linked, marked up documents (also referred to as pages). The browser 104 can also interface with standalone programs that do not use marked up documents. In this example, the browser 104 is executing with the wireless application 106. The browser 104 is described in greater detail below.

The wireless application 106 represents one of many predefined applications that are stored locally on the wireless communications device 100. Each wireless application represents a static portion of a web site tree. That is, this information does not change significantly over time. The web site tree is the data structure representing the hyperlinked web pages of a web site. (Note that the tree is actually usually a graph.) Each predefined application is used for accessing a different web site. The predefined applications can be downloaded to the wireless communications device 100 through wireless communications, but more typically, they are downloaded through a docking cradle or through infrared communications with another wireless communications device 100.

The wireless application 106, in this example, includes a number of hyper-linked pages. One of the pages includes the example query form 105. This example query form 105 is used to generate a query that is answered as the example query response 107. Alternatively, the wireless applications can standalone applications access through the browser 104. The applications can be C programs, JAVA programs, and/or compressed markup language (CML) or HTML pages.

The query response 107 represents the dynamic data in the web site tree (the data that can change often). The query response 107 includes information retrieved from the web server 140.

The example query form 105 and the example query response 107 can be stored in a CML format. The markup language is compressed relative to HTML. This compressed markup language is described in greater detail below. What is important is that the compressed markup language is a subset and superset of HTML and is requires far fewer bytes than HTML typically requires. Additionally, the compressed markup language represents a compressed description of information to be displayed on the screen 101. The browser 104 uses the representation to generate the display on the screen 101.

The base station 170 represents a wireless communications base station. The BSMD Mobitex system includes base stations like the base station 170. The base station 170 is responsible for communicating with the wireless communications device 100 and other wireless communications devices (e.g. pagers).

The private network 172 represents the communications links between a base station 170 and a proxy server 180. The BSMD Mobitex system has such a private network. Between the base station 170 and the proxy server 180, many servers, routers, and hubs, etc. may exist. In some embodiments, the private network 172 may communicate with the proxy server 180 through the Internet 190. The proxy server 180 would then communicate with the web server 140, also through the Internet 190.

The proxy server 180 represents one or more computers that convert queries from the wireless communications device 100 into queries that are compatible with Internet protocols. The proxy server 180 communicates with the wireless network, which can include low bandwidth and high latency communications. The proxy server 180 decompresses information from the wireless network side for use on the Internet 190 side of the proxy server 180. Also, the proxy server 180 converts Internet protocols and content into a form that can be used by the wireless network and the wireless communications device 100. in some embodiments, the proxy server 180 can converts image content to a size and bit depth appropriate for display on the wireless communications device 100. In some embodiments, the proxy server 180 communicates over the Internet 190 using standard Internet protocols such as, TCP, HTTP, and SSL. This allows developers to use already existing Internet protocols in their web servers.

In some embodiments, the proxy server 180 is substantially stateless. That is, it does not keep state information about specific wireless communications device accesses. This configuration of the proxy server 180 tolerates communication and protocol errors more readily and allows for simpler scaling of the proxy server 180. Statelessness should not be confused with caching. The proxy server 180 can cache CML web pages for use by multiple wireless communications devices 100.

In order to achieve reasonable performance and cost over wireless networks, the browser 104 works in tandem with the proxy server 180. The wireless communications device 100 and proxy server 180 communicate with each other using a compressed transport protocol (CTP) built on top of IP. The goal of this protocol is to enable a user to fetch and display a web page on the wireless communications device 100 with a one packet request sent to the proxy server 180. Typically, a one packet response is returned to the wireless communications device 100.

In one embodiment of the invention, the maximum packet size (for higher protowl packets, like IP) allowed over a low cost wireless network is 512 bytes. Taking into account a compressed header (usually three bytes), the maximum raw data size is 512−3=509 bytes.

The proxy server 180 transmits a typical page of web content to the wireless communications device 100 in roughly 500 bytes. This can be challenging given that most web pages have lots of formatting information, hot links and images. Web pages are typically many Kbytes in size. A hot link reference can easily take up 100 bytes or more. Just to fill the wireless communications device screen 101 with text (11 lines of 35 characters each) would take nearly 400 bytes even if there were no formatting information included.

This is why the wireless communications device 100 and the proxy server 180 use compressed web pages.

The Internet 190 represents the Internet. However, the Internet 190 could be replaced by any communications network.

The web server 140 responds to web accesses. The web server 140 serves regular, and specially constructed, HTML pages. In this example, the wireless communications device 100 is accessing the special HTML pages (e.g., HTML page 144). The example query response 107 corresponds to the HTML page 144. In other embodiments of the invention, the same HTML page can be served in response to a query from the wireless communications device 100 as is served to other types of clients. The HTML page 144 is generated by the CGI 142. The CGI 142 represents a program that can dynamically generate HTML pages in response to HTTP requests.

Turning to the query and response elements, the wireless CTP query 122 represents a compact transfer protocol (CTP) formatted query from the wireless communications device 100. The base station 170 receives this query and forwards it to the proxy server 180. The forwarded query is represented by CTP query 124. The proxy server 180 takes the CTP query 124 and converts it into one or more HTTP queries 126. The web server 140 receives this HTTP formatted query 126 and generates an HTTP response 136 that includes the HTML page 144. The proxy server 180 receives to the HTTP response 136, and generates the CTP response 134. The base station 170 generates the corresponding wireless CTP response 132. The wireless communications device 100 then generates the display on the screen 101 of the example query response 107. Before describing this process in detail, the browser 104 is described in greater detail.

Browser

The browser 104 and supporting wireless messaging programs comprise the client processing resources for some embodiments of the invention. The web browser 104 works well with both wireless and wireline connections, enabling users to seamlessly access the web whether they are connected through the phone line or not. The messaging support enables a user to send and receive wireless messages with other users that have Internet e-mail accounts.

The browser 104 support both wireless and wireline connections. An effective wireless browsing solution leverages the use of the proxy server 180 in order to deliver satisfactory performance. A solution embodied in the roles established for the wireless communications device 100 and the proxy server 180 dramatically reduces the amount of data that is sent between the wireless communications device 100 and the proxy server 180 over the slow wireless link. This form of browsing is referred to hereinafter as thin browsing.

The performance of wireline links, on the other hand, is high enough that a wireless communications device 100 can talk directly to a source of data such as a web content server using standard Internet protocols such as HTML, HTTP and TCP. This is how existing desktop browsers work and will be referred to hereinafter as standard browsing.

Thin browsing can be used over wireline links as well as wireless links. The only extra requirement is that the proxy server 180 be accessible to the wireless communications device 100 over the Internet or an intranet. Standard browsing, on the other hand, is more appropriately used over wireline links because of increased chattiness and bandwidth requirements.

The browser 104 is structured as a single user-interface that runs either a standard browser engine or a thin browser engine. With either engine, the user interface essentially appears the same, and the way original HTML web content is interpreted and displayed will be almost identical. The browser 104 relies on the proxy server 180 for reducing the amount of traffic and the number of transactions required. Although designed primarily for use over wireless networks, the browser 104 can be used over wireline networks as well.

The primary purpose of the thin browser engine is for accessing content designed specifically for the limited screen 101 size and functionality of a wireless communications device 100. For some embodiments, this layout and size are the only differences between content rendered for a wireless communications device 100 and existing desktops. Thus, content creators for desktop content can use the same tools that are used for creating and publishing desktop content when creating and publishing content for the wireless communications device 100.

Content rendered for the wireless communications device 100 can reside on standard HTML based web servers in standard HTML format (e.g., see web server 140). The proxy server 180 performs a dynamic conversion of the HTML content into the more compact CML form before transmitting the content to the wireless communications device 100.

The browser 104 will not prevent a user from accessing desktop oriented sites, but the browser 104 can behave differently when accessing them. For example, graphics can be ignored when not accessing a wireless communications device friendly site whereas the user will have the option to enable graphics for wireless communications device friendly sites. Another example of the difference is the browser 104 protects the user from unintentionally downloading a large desktop oriented site. A user option enables the user to set the maximum size desktop that may be downloaded. If a page is encountered which exceeds this maximum size, the page is clipped by the proxy server 180 before being sent down to the wireless communications device 100. The user is able to set this maximum size on a page per page basis in the favorites list of the browser 104.

When the user first launches the browser 104, the browser 104 is able to display the user's home page without sending or receiving even a single byte over the network. This is in contrast to the standard web browser that go over the network to fetch the home page, or at least to check that the locally cached version of the home page is up to date.

The browser 104 relies much more on pre-loaded content. A transaction typically takes place over the wireless network only when necessary. For example, in some embodiments of the invention, the browser 104 assumes that the locally cached form is up to date and only submits a network request to the proxy server 180 after the user fills in a form requesting an update.

Thus, the browser 104 is particularly suited for accessing real-time data, not casual browsing. Thus, emphasis is placed on optimizing the process of filling out a form (e.g., with airline flight information) then submitting the form, and getting the real-time data back. Although, the user will still be able to casually browse any web site, the increased cost and volume of data involved with going to most standard web sites makes casual browsing relatively undesirable over a wireless network.

A typical user scenario for the browser 104 would then be as follows. The user extends, or rotates, the antenna on the wireless communications device 100 and thereby automatically power up the wireless communications device 100. The browser 104 displays the user's home page (stored in local memory). The home page has been configured by the user with a set of service icons such as weather info, traffic info, airline info, stock quotes, etc. before the browser is used. The user clicks on one of the service icons, such as the airline information. This starts the corresponding wireless application which contains a form. The browser 104 displays the form (also stored in local memory) for the user to enter the flight number or city codes. The user enters the information in the form and hits the “submit” button. Now, for the first time in this scenario, the browser 104 sends a request out over the network to fetch the airline information. When the response comes back from the proxy server 180 (three to five seconds later), the information for that flight will be displayed on the screen 101.

As just described, there are a number of significant differences between the browser 104 and a standard web browser. First, the primary usage of the browser 104 is for accessing real-time data through form submittal. Second, most forms are pre-loaded into the wireless communications device 100 local memory or present in read only memory. Third, forms are assumed to be valid, and therefore no activity will take place over the network until the user actually fills in the form and submits it.

Browser and HTML Compatibility

The following describes the HTML compatibility of one embodiment of the browser 104. Other embodiments of the invention have different features.

In order to display most content published today on the Internet 190, the browser 104 supports the most common features of HTML. However, because of the screen size and limited memory and performance of wireless communications device 100, some HTML features may be limited in functionality or not supported at all.

Because of a limited number of available fonts and font styles, the browser 104 may not render every possible text attribute in HTML. A number of font sizes and styles map to the same font on the wireless communications device 100. However, the user does not encounter significantly reduced readability or usability as a result of the mapping.

The proxy server 180, as directed by the wireless communications device 100, can filters out all images, unless the user explicitly enables images, or the content author imbeds the appropriate tag into the content indicating that this page is wireless communications device 100 specific and that the images should be downloaded to the wireless communications device 100.

All text hyperlinks can be supported. If images are downloaded, then image maps will also work.

Forms will have nearly full functionality. The only feature of HTML forms that may not be supported is the use of dialogs that let the user choose a file name by browsing the local directory structure on the wireless communications device 100.

Tables that are too wide to fit on the screen can be wrapped.

CGI (Common Gateway Interface) scripts can be supported. CGI scripts are used by the web server 140 to respond to form submissions by browsers and for customizing web content for a particular user. When the browser 104 requests a web document that corresponds to a CGI script, the browser 104 can append text parameters to the end of the base document URL. The proxy server 180 will parse the parameters out of the URL and send them to an executable program on the web server 140, as identified by the URL. Most CGI executables will then output dynamically generated HTML that is consequently returned to the browser 104 and displayed. From the browser's 104 point of view then, fetching a web document that uses CGI scripts is no different from fetching a static web document (other than having a slightly more complex URL).

Example Method of Communicating Between a Wireless Communications Device and a Web Server

FIG. 2 illustrates a method of communicating between a wireless communications device and a web server. Such a method can be implemented using the system of FIG. 1.

The example method of FIG. 2 can be broken into three processes: a build a distributed web site process 202, a query process 204, and a response process 206. By using these three processes, a distributed web site can be created where static information is primarily kept on the wireless communications device 100 and dynamic information is kept on the web server 140.

At block 210, a content developer defines a wireless application. In one embodiment of the invention, this includes defining a number of HTML pages. The HTML pages represents the forms used for querying the web server 140. A program is then used to convert the HTML pages into compressed markup language pages to generate the wireless application 106. This process is discussed in greater detail below in the compressed markup language section.

At block 220, the web server 140 is created, or modified, to support reduced content HTML pages. An example of such a page is shown as HTML page 144. These pages can be generated exactly the same way as regular HTML pages. However, as a guiding principle, the amount of information should include little more than the absolute minimum of information that a user would find useful.

At block 230, a user loads the wireless application 106 onto the wireless communications device 100. This can be done as a HotSync™ operation in a manner similar to the way in which other applications are loaded onto the wireless communications device 100. The wireless communications device 100, for example, can be connected to a computer via a cradle and the wireless application 106 can be loaded from the computer. Alternatively, the wireless application 106 can be downloaded over the wireless network. However, this second method of loading the wireless application 106 is less desirable in that it will require a significant amount of bandwidth. Thus, in a preferred embodiment, the user loads the wireless application 106 over a high bandwidth network (e.g., the cradle download or by an infrared transfer from another wireless communications device 100).

Thus, some of the web site information is stored on the wireless communications device 100 and some of it is stored in the web server 140. Thus, the building of the distributed web site process 202 has been described.

The query process 204 includes the following steps. At block 240, the user fills in a query form 105 as part of the wireless application 106. In the example of FIG. 1, the user is filling out a form to find Italian restaurants in San Francisco. Once the user has completed the form, the user selects the look up button. The look up button causes the wireless communications device 100 to initiate the wireless CTP query 122. The block 240 is completed by the sending of the wireless CTP query 122 and the CTP query 124 to the proxy server 180. The wireless CTP query 122 is sent to the base station 170. The base station 170, and related hardware, perform any necessary changes to the wireless CTP query 122 to generate the CTP query 124, and send the CTP query 124 over the private network 172.

At block 250, the proxy server 180 converts the CTP query 124 to an HTTP query 126 and forwards that HTTP query 126 to the web server 140. Thus, the query process 204 is completed.

Now the response process 206 is described. At block 260, the web server 140 generates and sends an HTML page 144 to the proxy server 180. At block 260, the web server 140 generates the HTTP response 136 in response to the HTTP query 126. In this example, because the HTTP query 126 corresponds to a wireless communications device 100 query, the web server 140, and in particular the CGI 142, sends the HTML page 144 in the HTTP response 136. Returning to block 250, the conversion from the CTP query 124 to an HTTP query 126 may involve more than one HTTP request. This may occur where the web page has multiple referenced objects that need to be retrieved from the web server 140. Thus, the proxy server 180 may initiate multiple requests depending on the response in block 260. Note however, only one CTP request was needed.

At block 270, the proxy server 180 converts the HTML page 144 into the example query response 107 and sends the example query response 107 to the private network 172. The example query response 107 is inside of the CTP response 134, which is transmitted from the proxy server 180, across the private network 172, to the base station 170. The base station 170 then sends the corresponding wireless CTP response 132 to the wireless communications device 100.

The operating system 102 notifies the browser 104 that the wireless CTP response 132 has been received. The browser 104 requests the contents of the wireless CTP response 132 from the operating system 102. The contents are the example query response 107. Thus, at block 280, the browser 104 can display the example query response 107 on the screen 101.

Example User Interface

FIG. 3 includes a number of pictures showing an example display generated by the wireless communications device 100. These displays would be generated when a user attempts to find restaurants in San Francisco.

The wireless communications device 100 includes a launcher under which wireless applications can be grouped. The launcher interface 303 displays the list of available wireless applications. Note that the browser 104 is not specifically listed. This is because the user would typically only want to run a specific web site access application, not the browser 104 by itself. In this example, the user has selected “fine food” from the launcher interface 303.

In response to the selection, the example the browser 104 and the wireless application 106 begin executing. The browser 104 displays the example query form 105. The example query form 105 is a CML page in the wireless application 106. Then, the user can select/enter various field values for a query. In this example, the user is selecting the location field value “San Francisco”.

The completed query form 305 is shown next. The user now wishes to send the query. This can be done by selecting the “look up” button. This sends the wireless CTP query 122 out through the network and to the web server 140. The wireless communications device 100 then receives the wireless CTP response 132.

The response includes the information for the example query response 107. The browser 104 displays the example query response 107 on the screen 101. Here a number of restaurant names and phone numbers are shown. The user can scroll up and down through the list.

Also presented on the screen 101 is a toolbar 310. The toolbar 310 allows the user to perform various functions within the browser 104. The toolbar 310 includes a back button, a connection indicator, and a drop down list. The back button allows the user to go back to the previous query form. The wireless communications indicator indicates whether the wireless communications device 100 is performing a wireless communications query. The drop down list indicates a history of the query results that the user has requested during past use of the browser 104.

Wireless Network Topology

FIG. 1 and FIG. 4 show the general topology of a wireless communications network. As shown, the wireless client 405 (in FIG. 4, the wireless communications device 100 and its software have been combined into the wireless client 405) communicates directly with the proxy server 180. The wireless client 405 does not communicate directly with the actual source of data. The source of data can be a web or mail server that has content desired by the wireless client 405. FIG. 1 shows the Internet 190 as the source of data and the source of data will be referred to as the Internet 190 throughout this application. Using this scheme, the wireless client 405 and the proxy server 180 can use a much more efficient (“thin”) protocol between themselves than used by Internet mail and web servers. On the other hand, the proxy server 180 uses standard Internet protocols (HTTP, TCP) when communicating with existing mail and web servers. The proxy server 180 acts as an agent. The proxy server 180 takes requests from the wireless client 405, obtains the requested information from the Internet 190, and re-formats and sends the requested information back to the wireless client 405. The proxy server 180, acting in this manner, can hide the relatively chatty and bandwidth intensive protocols used by standard Internet 190 servers from the wireless link.

The thin protocols used between the wireless client 405 and the proxy server 180 are IP based. IP based protocols are widely used and enable the wireless client 405 to communicate with many different wireless networks. Furthermore, basing wireless client 405 and proxy server 180 processing resources on IP provides a layer of isolation and independence from the actual wireless network in use.

FIG. 4 shows a wireless network topology 400 used for some embodiments of the invention. The main components of the wireless communications system are the wireless client 405, the wireless network access point 410, the tunneler 430, the proxy server 180, and the Internet 190. The wireless network access point 410 has a corresponding wireless network access point radio 420.

The wireless client 405 communicates across the wireless network using its own client radio 440 to transmit messages to and receive messages from the wireless network access point radio 420. The wireless network access point 410 is the nearest regional station in a wireless network with a connection to a proxy server 180. The wireless network is by nature not IP based, and its most basic packet type is referred to herein as wireless network protocol packet (WLNP). Consequently, the wireless client 405 encapsulates its IP packets with a WLNP header before the packets can be sent by the client radio 440.

The packets sent over the air include a number of headers in the following order: a WLNP header, followed by a compressed user datagram protocol (C-UDP) header, followed by a reliable message protocol (RMP) header. The headers encapsulate a Request/Response Message Fragment (RQMF/RSMF) of the packet. The RQMF/RSMF of each packet holds the message fragments. These fragments are commands, requests, and responses sent between a wireless client 405 and the proxy server 180 that enable a wireless client 405 to browse web pages, send and receive e-mail, and otherwise obtain access to content.

In some embodiments, the wireless network has guaranteed delivery built into it. For these embodiments, it is not necessary to incur the extra overhead of a full connection-oriented protocol such as TCP on top of the wireless network protocol. Instead, the wireless client 405 uses the Internet 190 UDP. The UDP is a simple datagram based, best effort delivery protocol. Using UDP, it is possible that a web page can be viewed from the wireless client 405 by sending just one packet up to me proxy server 180 and receiving just one packet back. The TCP protocol, on the other hand, would require a minimum of 5 packets back and forth between the proxy server 180 and the wireless client 405 to view the web page. The wireless network does not, on the other hand, guarantee order of delivery, so an RMP header is placed in front of the data area in each UDP packet. The RMP is used to detect and correct for out-of order or duplicate packet deliveries.

Instead of using raw UDP internet headers which are 28 bytes in length (20 bytes for the IP information, 8 bytes for the UDP information), the wireless client 405 uses a smaller, compressed form of the UDP header called C-UDP. A C-UDP header contains just enough information so that the actual IP/UDP header can be reconstructed at the other end of the wireless link. There are a number of fields in a standard IP/UDP header that are rarely changed and/or redundant over the wireless network and these fields can be highly compressed or left out altogether in the C-UDP header, as discussed in greater detail below.

The wireless network access point 410 receives WLNPs that have C-UDP packets imbedded in them. The WLNP header is stripped off the front of the packets by the tunneler 430 for the wireless network. The original IP header and UDP header are reconstructed, and the packets are then forwarded to the proxy server 180 through a TCP connection. Because an unreliable network (LAN or Internet) is used between the wireless network tunneler 430 and the proxy server 180, TCP is used to guarantee that the packets get transferred reliably.

The TCP stream that the proxy server 180 receives from the tunneler 430 has the imbedded IP packets. The IP packets contain request message fragments. The reliable message layer (shown in FIG. 6 as reference number 635) on the proxy server 180 reconstructs the original request message from the message fragments in the packets using the information contained in the RMP header area of each packet. The requested information (web page or e-mail) is then be fetched as a data object from the Internet 190, re-formatted, and passed back to the reliable message layer 635. Proxy server 180 processing resources operating in the reliable message layer 635 break down the data object into separate packets for transmission to the wireless client 405, and send the packets to the tunneler 430 through the TCP connection. The tunneler 430 forwards the packets back over the wireless network to the wireless client 405.

FIG. 5 illustrates the wireless network topology including a wireless network interface 510, a wireless network leased line 520, and a dispatcher 530. FIG. 5 shows how the wireless client 405 and proxy server 180 communicate when the wireless client 405 is on a wireless network. Notice that the wireless client 405 is directly on the wireless network whereas the proxy server 180 is not. The wireless packets do not get sent directly to the proxy server 180. Instead, they first pass through the base station 170, a wireless access point 410, and tunneler 430 before they are sent to the proxy server 180 over a wireline LAN (Local Area Network) connection.

Wireless client 405 processing resources send messages through the reliable message layer 635. Since the wireless client 405 is on a wireless network, the reliable message layer 635 uses the RMP protocol to send the messages. The RMP protocol encapsulates the message fragments with an RMP header and sends them through a UDP socket in the network library (shown as 1110 in FIG. 11 and discussed below). The packets work their way through the IP stack on the wireless communications device 100, which adds UDP header and IP header. The packets are passed down to the wireless network interface 510 for transmission.

The wireless network interface 510 then compresses the IP header and UDP header of the packet into a C-UDP header, and adds the wireless network protocol (WLNP) header. FIG. 5 shows the wireless network interface 510 adding a WLNP header that is used on the wireless packet data network. Other networks will have similar headers. Much of the information in the IP and UDP headers is redundant with the WLNP header, so the C-UDP header can be significantly smaller than the sum of the IP header and UDP header.

The WLNP encapsulated packets are sent over the radio and are received by a base station 170. The base station 170 passes them to a wireless network access point 410. The wireless network access point 410 then passes the packets through a wireless network leased line X.25 link to the tunneler 430. The X.25 link can be a 56 Kbps leased line or a high speed frame relay connection. Although FIG. 5 shows only one tunneler 430, two tunnelers are typically used for the wireless packet data network. In one embodiment, the first tunneler is part of the wireless packet data network infrastructure and is referred to as the “Internet Access Server” or IAS. The IAS tunnels the WLNPs from the wireless network access point 410 into a TCP stream and sends this stream to a proxy server 180 specific tunneler. The proxy server 180 tunneler takes each WLNP from the IAS stream and converts its WLNP/C-UDP headers into normal IP/UDP packet headers. Thus, at this point in the chain of events, the packets look identical to the way they looked when the wireless client 405 first passed them to the wireless network interface 510 on the wireless communications device 100.

The tunneler 430 then sends its output stream to a dispatcher 530. The dispatcher's job is to load balance among multiple proxy servers 180. The dispatcher 530 distributes wireless client 405 requests that the dispatcher 530 receives from the tunneler 430 among a set of proxy servers 180. In order to do this, the dispatcher 530 checks the source IP address and UDP port number on each packet to determine whether the packet corresponds to a new transaction. If the packet corresponds to a new transaction, the dispatcher 530 selects the proxy server 180 with the lightest load and sends the packet to that proxy server 180. If the packet does not correspond to a new transaction (i.e. the 2.sup.nd packet of a two packet request), the dispatcher 530 looks up the proxy server 180 used for the previous packet of this transaction and sends the packet to that same proxy server 180.

Finally, the packets are received by the proxy server 180. The proxy server 180 gathers the request packets from the dispatcher 530, reassembles them into the original CTP request message, processes the request, forms a response, breaks the response down into separate IP/UDP/RMP packets, and then sends the response packets back through the TCP socket to the dispatcher 530.

The proxy server 180 receives entire IP packets imbedded in the TCP stream that the proxy server 180 receives from the dispatcher 530. These packets are re-ordered and re-assembled into the original message before the request is processed. The IP, UDP, and RMP headers are stripped off and the information in the RMP and UDP headers used to re-construct the original request message. When a response message is formed, the response message is split into separate packets as necessary. IP, UDP and RMP headers (with source and destination machine addresses and port numbers swapped) are pre-pended to the packets before they are sent via TCP to the dispatcher 530 where the packet continues its journey back to the wireless client 405.

A few important points should be noted about this wireless setup. First, the only components that are specific to the wireless network are the wireless network interface 510 on the wireless client 405, and the tunneler 430 at the proxy server 180. The wireless client 405 application software, reliable message layer 635 and all of the software on the proxy server 180 are strictly IP based and do not have to change if a different wireless network is used.

Second, the tunneler 430 and the dispatcher 530 are not required to be placed on the same physical machine as the proxy server 180. If the tunneler 430 and the dispatcher 530 are on the same machine as the proxy server 180, the LAN link between the three system elements becomes a virtual TCP connection through the IP stack on the proxy server 180. This may seem to be preferable from a performance point of view, but, there are many more advantages to having the dispatcher 530 and proxy servers 180 on separate machines. If the dispatcher 530 is on a separate machine, the dispatcher 530 can distribute wireless client 405 transactions among multiple proxy servers 180, thereby providing both scalability and fault tolerance. If any one of the proxy servers 180 become inoperative, the dispatcher 530 can stop sending requests to the inoperative proxy server 180. Because the communications system has multiple proxy servers 180 the dispatcher 530 can distribute the load between them. The dispatcher 530 therefore becomes the most sensitive link in the chain from a fault tolerance point of view. But, from a performance point of view, the dispatcher 530 has very little work to do for each transaction compared to the proxy server 180 so it makes sense to have multiple proxy servers 180 per dispatcher 530 (and tunneler 430). If necessary, multiple tunnelers 430 and dispatchers 530 can be placed in parallel to provide even more fault tolerance and scalability.

A third important point is that the only unreliable link in the whole chain is over the wireless network, i.e., between the wireless network interface 510 on the wireless client 405 and the base station 170. In particular, the link between the base station 170 and the proxy server 180 is a reliable link all the way through. The RMP logic on both the wireless client 405 and proxy server 180 is simplified because the RMP logic only corrects for lost and unordered packets over the wireless network, not the wireline network between the base station 170 and the proxy server 180. This simplified RMP logic enables the timeout values used for re-transmission attempts to be tuned for just the wireless portion of the network.

Intranet Topology

A corporate wireless Intranet is setup in the same manner as the Internet solution just described. The only major difference is the physical location of the machines. For the Internet solution, the proxy server 180 is located at the wireless network access point 410 and has a connection to the global Internet. For a corporate Intranet solution, the proxy server 180 is located at the corporation's own private site with a leased line to the nearest wireless network access point 410. The leased line transports the WLNPs between the wireless network access point 410 and the corporation's own tunneler and proxy server 180. The proxy server 180 has a direct connection to the corporation's private Intranet.

Content Layer

This section covers the implementation of the wireless communications device 100 content layer. The content layer deals with how web content and personal messages are formatted and rendered on the wireless client 405. In particular, this section discusses the Hypertext Markup Language (HTML) and Compact Markup Language (CML) page description languages.

When using the standard browser engine, the wireless client 405 web browser application renders HTML obtained directly from the web content server. When using the browser 104 however, the wireless client 405 renders CML which has been dynamically generated from HTML by the proxy server 180.

When the wireless client 405 e-mail application sends or receives personal messages with the proxy server 180, it also uses CML to format the messages. Sending and receiving graphically formatted messages is not a specified requirement of the wireless communications device 100, but CML is used for the message format because it also provides excellent raw text compression. An added benefit is that CML provides the framework required for graphically oriented messaging applications.

There are two basic challenges in the design of the browser 104. The first is effectively rendering existing web content on a very small screen. The second challenge is minimizing the amount of data that is sent over the wireless network when using the browser 104 engine.

The HTML page description language works fine for answering the first challenge, but is not an appropriate choice for answering the second challenge. HTML was designed as an “ideal” language for creating content. HTML is human readable, human editable, and screen size and depth independent. This makes it a very good general purpose page description language, but also a very verbose language and too large to transmit wirelessly.

CML answers both challenges because CML also minimizes the amount of data that is sent over the wireless network. In order to achieve its minimal size, CML sacrifices both human readability and editability.

As a further optimization, the CML is created dynamically at run-time by the proxy server 180 using knowledge of the screen size and depth of the wireless client 405. Thus, the wireless client's 405 very limited screen 101 functionality will enable the proxy server 180 to generate a much smaller CML representation than the proxy server 180 could otherwise. For example, elements that do not fit on the wireless client 405 screen 101 could be left out altogether and images that are too deep for the wireless client 405 screen 101 are depth converted before being transmitted.

Ideally, the user is not aware of whether CML or HTML is used to render content. Therefore, both page description languages provide the same feature set. However, the implementation of the two languages is significantly different because CML provides the necessary compression to accommodate the wireless network bandwidth. To accomplish these goals, CML is optimized for small wireless clients 405. However, alternate and larger forms of representation can be used to implement the full feature set of HTML when necessary.

This following provides a description CML, followed by descriptions of HTML features, how each HTML feature is displayed and used in the browser 104, and finally how that feature is represented using CML. Keep in mind that the appearance of a HTML feature is independent of whether or not it is sent to the wireless client 405 in raw HTML format or as CML.

Compact Markup Language (CML)

In order to send web content to the wireless client 405 in a minimal number of bytes, the proxy server 180 does not use the HTML standard generally used by Internet servers. In HTML, all the tags and attributes associated with text, tables, forms, etc are text based, typically take up from 3 to 10 bytes each, and are stored both at the beginning and end of the text that they modify. For example, to display emphasized text, a web document would have to contain the following HTML sequence: <STRONG>This is emphasized text</STRONG>.

The wireless client 405 and the proxy server 180 use a special format for transferring screen 101 contents from the proxy server 180 to the wireless client 405. This format, named Compact Markup Language (CML), emphasizes compactness over readability and generally uses variable length binary bit fields instead of text to represent options and formatting information. The differences do not end there however; CML will use a host of other methods for reducing the number of bytes that is sent between the proxy server 180 and the wireless client 405.

CML compresses all text. In one embodiment, the default CML compression scheme formats text using a form of a five-bit character alphabet with escapes. This default compression scheme works best with pages that have mainly lower case alpha letters in them, but does allow for a full range of characters including characters with ASCII values greater than 128.

CML also leverages the fact that the proxy server 180 knows the screen size and bit depth of the wireless client 405 when encoding the layout of the content. HTML was designed to be screen independent—neither the server nor the content creator knows ahead of time what size or depth screen upon which the document will eventually be rendered. Besides the obvious advantage of not sending content that wouldn't fit on the wireless client 405 screen 101, there are other cases where content can be encoded in a more compact form by the proxy server 180 because it knows the size of the wireless client 405 screen 101. Since the proxy server 180 also knows the bit depth of the wireless client 405, the proxy server 180 can also reduce the data sent to the wireless client 405 by not sending color attributes such as the background color, text colors, underline colors, etc.

The major emphasis of CML is that it is optimized for size. In other words, readability and flexibility are compromised for compactness. One major design philosophy difference between HTML and CML is that CML is not designed as a content creation language. CML is merely a temporary format used to represent content as it is being transferred between a proxy server 180 and a wireless client 405. As such, CML is algorithmically generated, much like object code is generated from a compiler. The analogy to compilers is even stronger when you take into account the fact that CML is generated with the screen size and attributes of the wireless client 405 taken into account. The same HTML content can produce different CML representations for two wireless clients 405 that have different screen sizes—much like compilers for different microprocessor produce different object code from the same source code.

Essentially, CML is a stream of text and image data with imbedded formatting commands (tags). The tags are imbedded as binary data and hence are very compact. Every tag is “sticky”; that is the tag continues to have an effect until explicitly changed by another tag of the same type. For example, a tag in the front of a document that specifies bold text makes the entire document bold, unless another tag later in the document turns off the bold formatting. This is in contrast with many HTML tags, such as paragraph formatting commands, that only affect the next paragraph.

Another important difference between CML and HTML is that white space and line breaks in the text are significant. For CML, the equivalent of the HTML line break tag (<BR>) is not required in CML since line breaks are imbedded directly into the text.

The default behavior of CML is to compress all text by encoding it using a special 5-bit character alphabet discussed below in the CML Structure section. This form of compression works best for documents that are mainly comprised of lower case roman characters. Other forms of text encoding, including 8 bit ASCII, unicode, etc. are used in CML only when necessary.

Using CML and the CML structure described below combined with CTP formatting of forms, some embodiments of the invention comprise a method for transmitting a message from a wireless client 405 to a proxy server 180. The method comprises transmitting a single message from the wireless client 405 to the proxy server 180. The single message comprises a single packet of data. The single packet of data having a base document uniform resource locator followed by compressed data. The compressed data comprises references to fields in a hyperlink document and an indication of use of the hyperlink document. The hyperlink document is in the base document. In some embodiments, the size of the single packet of data is less than one kilobyte.

In some embodiments, the references to fields comprise field values and field indices corresponding to fields in the hyperlink document. In some embodiments, the base uniform resource locator is expressed in a compact transfer protocol by a binary string. The binary string comprises a first field indicating the encoding scheme used for the single message.

Some embodiments of the invention comprise a method for securely transmitting a message from a wireless client 405. The method for securely transmitting comprises encrypting a data encryption key, encrypting the message using the data encryption key, and transmitting the encrypted message to the proxy server 180. The wireless client encrypts the data encryption key using a proxy server 180 public key to form the encrypted data encryption key. The data encryption key corresponds to a specific transaction between the wireless client 405 and the proxy server 180. The wireless client encrypts the message using the data encryption key to form an encrypted message. The wireless client 405 transmits the encrypted message to the proxy server. The encrypted message comprises at least one packet of data. In some embodiments, each packet of data is formatted according to a compact transfer protocol.

In some embodiments, prior to encrypting the data encryption key, the method further comprises the step of generating the data encryption key. The data encryption key is generated by the wireless client 405 for a specific transaction between the wireless client 405 and the proxy server 180. Generating the data encryption key comprises applying a secure hash to a first input to form a first multibit hash, and applying a message digest function to the first multibit hash to form the data encryption key. The first input comprises a concatenation of an output from a random number generator and at least one other character string.

In some embodiments, the message comprises a request message corresponding to a hypertext document. The encrypted request message further comprises encrypted request parameters, an encrypted bit, an encryption scheme identifier, a proxy server public key identifier, a proxy server identifier, a wireless client generated indication of current date and time, an encrypted request message integrity check, and the encrypted data encryption key. The encrypted request parameters are created from request parameters using the data encryption key. The request parameters comprise compressed representations of data corresponding to fields in the hypertext document. The compressed representations are formatted according to a compact transfer protocol. The encrypted request message integrity check is encrypted using the data encryption key.

In some embodiments the method for securely transmitting the message from the wireless client further comprises validating the encrypted request message after transmitting the encrypted request message. Validating comprises comparing the wireless client generated indication of current date and time with a proxy server indication of current date and time. If the difference in these times is greater than a predetermined value (such as twenty-four hours), the proxy server 180 throws away the encrypted request message. If the difference in these times is smaller than the predetermined value, the proxy server 180 processes the encrypted request message and forms a response message.

In some embodiments, the proxy server 180 retains wireless client 405 generated indications of current date and time corresponding to each encrypted message received by the proxy server from the wireless client 405 prior to the wireless client 405 transmitting the encrypted request for a predetermined time. The method for securely transmitting the message from the wireless client 405 further comprises validating the encrypted single request message after transmitting the encrypted request message. Validating the encrypted request message comprises determining whether the wireless client 405 generated indication of current date and time submitted with the encrypted request message is less than or equal to any of the retained wireless client generated indications of current date and time. If the wireless client generated indication of current date and time submitted with the encrypted request message is less than or equal to any of the retained wireless client generated indications of current date and time, the proxy server throws away the encrypted request message. If the wireless client 405 generated indication of current date and time for the request message is greater than all of the retained wireless client 405 generated indications of current data and time, the proxy server 180 processes the encrypted request message and forms a response message.

In some embodiments, the specific transaction comprises a single request message and each packet of data is less than one kilobyte.

Some embodiments of the invention comprise a method for securely transmitting a message from a proxy server 180 to a wireless client 405. The method for securely transmitting comprises the following steps. The wireless client 405 encrypting a data encryption key using a proxy server public key to form an encrypted data encryption key. The proxy server receiving the encrypted data encryption key. The proxy server recovering the data encryption key. The proxy server encrypting the message using the data encryption key. The proxy server transmits the encrypted message to the wireless client. The data encryption key corresponds to a specific transaction between the proxy server and the wireless client. The proxy server recovers the data encryption key by decrypting the encrypted data encryption key using the proxy server private key. The proxy server encrypts the message using the data encryption key to form an encrypted message. The encrypted message comprises at least one packet of data. In some embodiments, the message comprises compressed data in a compact markup language. In some embodiments, the specific transaction comprises a single response message, and each packet of data is less than one kilobyte.

In some embodiments the method for securely transmitting a message from the proxy server 180 further comprises the following steps prior to recovering the data encryption key. The proxy server 180 receives an encrypted request message comprising encrypted request parameters, a wireless client 405 generated indication of current data and time, and a proxy server 180 identifier. The proxy server 180 receives an encrypted wireless client 405 generated request message integrity check. The encrypted request parameters are formed by encrypting request parameters using the data encryption key. The encrypted request message integrity check is formed by encrypting a wireless client generated request message integrity check using the data encryption key. The client generated request message integrity check is formed from a concatenation of the request message parameters, the wireless client generated indication of current data and time, and the proxy server identifier.

In some embodiments, the message transmitted from the proxy server 180 to the wireless client 405 comprises a response massage. The method for securely transmitting a message from the proxy server further comprises the following steps before the transmitting step. The proxy server computing a response message integrity check. The proxy server encrypting the response message integrity check using the data encryption key to form an encrypted response message integrity check. The encrypted response message further comprises the encrypted response message integrity check.

Some embodiments of the invention comprise a system for secure communications. The system for secure communications comprises a source of data, a wireless client 405, and a proxy server 180. The source of data comprises means for transmitting HTML messages to the proxy server 180. The wireless client 405 comprises means for exchanging encrypted messages with the proxy server 180. The encrypted messages comprise encrypted request messages and encrypted response messages. Each encrypted message comprises at least one packet of data. Each encrypted request message comprises encrypted request parameters and an encrypted data encryption key. The request parameters corresponding to fields in a hypertext document. The HTML messages corresponding to the encrypted request messages. The proxy server 180 is in communication with the wireless client 405 and the source of data. The proxy server 180 comprises means for exchanging encrypted messages with the wireless client, means for fetching HTML messages from the source of data, and means for recovering the data encryption key.

Strength and Possible Attacks

The strength of the wireless communications system security is roughly equivalent to that provided by 128-bit versions of SSL. However, there are possible attacks and this section provides an overview of the possible attacks and counter measures employed to prevent them.

Attackers can be broadly classified into one of two categories: passive and active. Passive attackers are eavesdroppers who can listen in on a conversation and glean useful information from either one of the parties but otherwise do not take an active part in the conversation. Active attackers can actually take part in the conversation by impersonating one of the parties by modifying messages sent between the two parties, or by interjecting extra messages into the conversation.

Wireless networks are considered particularly susceptible to passive attacks because all that is required is a radio receiver, and there is nearly zero-chance of being detected. Active attacks on the other hand are easier to detect since most wireless networks have mechanisms for detecting and shutting down invalid transmitters (through Electronic Serial Numbers).

Passive Attacks

The wireless communication system resistance to passive attack is provided through a combination of encryption algorithms. The wireless communication system uses two encryption techniques: public key (public/private) and symmetric. Public key encryption is used to send a symmetric encryption key from the wireless client 405 to proxy server 180 and symmetric encryption is used to encrypt the actual message data. This combined approach leverages the strengths of the two encryption techniques while providing maximum security.

Public key encryption has the unique quality that data encrypted with the public key can only be decrypted with the private key. This is ideal for wireless communications system because the proxy server 180 private key can remain secret on the proxy server 180 and each wireless client 405 only needs the proxy server 180 public key. Therefore, any of the wireless clients 405 can encrypt data for transmittal to the proxy server 180. No one (including the sender) other than the proxy server 180 can decrypt the data once the data has been encrypted.

On the other hand, public key algorithms are much (i.e., orders of magnitude) slower than symmetric algorithms and are particularly susceptible to chosen plaintext attacks. The chosen plaintext attacks are conducted by a malicious party who selects chosen data to be encrypted with the private key. The malicious party is then able to deduce the private key from the resulting cyphertext.

In order to work around the slower performance and weakness to chosen plaintext attacks of public key encryption, the message data is encrypted using a symmetric algorithm and the slower public key algorithm is only used to encrypt the symmetric key. The symmetric data encryption key (DEK) is randomly generated so that chosen plaintext attacks can not be mounted.

Active Attacks

The wireless communication systems resistance to active attack is provided by inclusion of the message integrity check (MIC), dateTime stamp, and proxy server 180 ID fields. The combination of these elements insures that an active attacker will not be able to modify, or replay a message without being detected. If any portion of the message data is modified, the MIC will be invalid. Furthermore, because the MIC is encrypted, the MIC can not be re-generated by an active attacker without knowledge of the DEK or the proxy server (180) private key.

Resistance to replay attacks is provided by inclusion of the dateTime and serverID stamps. The proxy server 180 keeps a record of the last dateTime stamp received from each wireless client 405 within the last 24 hours. If a duplicate dateTime stamp is detected by the proxy server 180, the proxy server rejects the request by the attacker. The proxy server 180 also performs a bounds check on the dateTime stamp and rejects the request if the dateTime stamp is off by more than 24 hours in either direction. Thereby, the proxy server 180 can safely dispose wireless client 405 dateTime stamps once the dateTime stamps become more than 24 hours old. The serverID stamp is included to foil replay attacks to a different proxy server 180. If an attacker tries to replay a request sent to proxy server A by sending it to proxy server B, proxy server B will reject the request since the serverID will not match.

Another possible attack is for someone to impersonate the base station 170 and proxy server 180. The attacking rogue server would attempt to force the wireless client 405 to accept a new public key as part of the public key rejection mechanism outlined above in step number 7 above. In order for this attack to be successful, however, the rogue server must know the private key of the real proxy server 180. Furthermore, the rogue server must be able to receive and transmit messages using the unique identification number of the real proxy server 180. Thus, although an attack premised on impersonation of a base station 170 and a proxy server is possible, such an attack would be very difficult to mount. To further reduce the risk of this attack, the wireless client 405 software asks user permission through a dialog before accepting a new public key from the proxy server 180. Users are forewarned, through means other than the wireless network (e.g., wireline e-mail, or hard copy delivery) when a proxy server 180 public key is changed so that “legal” changes to the proxy server 180 public key do not come as a surprise to a user. Because the user knows of any legal change to the proxy server 180 public key before the change is made, base station 170 and proxy server 180 impersonation attacks can be defeated by user denial of permission to use new public keys that are not accompanied by appropriate user notification.

Encryption Algorithms

Algorithms that provide adequate protection using the wireless communications system encryption scheme include ElGamal or Elliptic Curve for the public key algorithm, and a-way or Triple-DES for the symmetric algorithm. These algorithms are attractive because they provide high levels of security.

Administration

To ensure that the wireless communications system security is effective, the proxy server(s) 180 are located in a secure site. Because the proxy server 180 decrypts data before using SSL to transfer it to the content server, the unencrypted content reside in the proxy server 180 memory for short periods of time.

Furthermore, knowledge of the proxy server 180 private key would enable eavesdroppers to listen in on conversations between wireless clients 405 and the proxy server 180 and undermine the entire security scheme. Thus, the proxy server 180 private key is kept under complete confidence. To maintain the secrecy of the private key, the unencrypted private key never appears on paper or in electronic form, but rather is encrypted using a sufficiently long pass phrase that must be entered by a proxy server 180 administrator at run-time.

Reliable Message Layer and Reliable Message Protocol

This section describes the reliable message layer 635 of the wireless communications device 100. The reliable message layer 635 provides reliable, efficient delivery of arbitrary length messages over both wireline and wireless networks. The protocol it uses over wireless links is called the reliable message protocol (RMP). When operating over wireline links, it uses the Internet standard TCP protocol.

In terms of functionality, the reliable message layer 635 is situated below the transfer layer and above the network layer. The network layer is the layer responsible for sending packets over the network. On a wireless communications device 100, the network layer is the wireless communications device 100 operating system 102 network library (also referred to as NetLib, and shown as Net Library, reference number 1110 in FIG. 11).

When operating over a wireline network, the reliable message layer 635 will uses the TCP Internet protocol. TCP provides guaranteed delivery of stream data and works well over networks that have relatively high bandwidth and low latency. By following a few simple usage rules that are described below, the TCP protocol is easily adapted to send discrete messages instead of stream data.

When operating over a wireless network, the reliable message layer 635 will instead use the RMP protocol. RMP is used because TCP is not practical over high latency low bandwidth networks. RMP is much more efficient than TCP and is optimized for use in an environment where small requests and responses are transferred between the wireless client 405 and the proxy server 180.

On Wireless Networks

The reliable message layer's job is to reliably send and receive messages with the remote host. A message is simply a block of data that represents either a request from a wireless client 405 to a proxy server 180, or a response from a proxy server 180 to a wireless client 405. These messages can in general be any size but the majority of them will be small enough to fit within a single wireless network packet.

Some messages will be too large to fit within a single packet. RMP therefore provides a mechanism to identify packets in such a way that the receiving host can reconstruct the message as each packet arrives. Furthermore, the packets are not guaranteed to arrive in the same order they were sent out, so the receiving host is also prepared to re-order them.

In some embodiments wireless networks do not guarantee delivery of packets. For such networks, RMP provides a mechanism for re-transmission of packets that are not received by the remote host. This mechanism is adapted to minimize any unnecessary traffic over networks that have guaranteed delivery.

Finally, RMP is extremely efficient in its use of network bandwidth. Wireless networks typically have a very high latency for every packet, no matter how small the packet size. For example, a one byte packet on a packet data network typically takes an average of 3 seconds just to travel from a remote wireless client 405 to the proxy server 180. To reduce overall latency then, most transactions should be accomplished with just one packet sent from wireless client 405 to proxy server 180 and just one packet returned. To reduce bandwidth, the header space used by RMP is minimal.

The following table summarizes these design goals of RMP:

1.) Minimal If both the request and response messages are less number of than 1 packet in length, an entire transaction should packets take place with just 1 packet sent from wireless client 405 to proxy server 180 and just 1 packet returned. 2.) Minimal The packet header used by RMP is minimal in size header size and optimized for small messages. 3.) Correct for RMP works over networks that do not guarantee out-of-order order of delivery. In particular, messages that do not delivery fit within a single packet are correctly reconstructed at the receiving host even if the packets arrive out of order. 4.) Correct for When operating over networks that do not guarantee lost packets delivery of packets, RMP automatically re-transmits packets as necessary. This mechanism is adapted to abide by the one packet up one packet down goal when operating over networks that do provide guaranteed delivery.

The RMP Header

The following structure defines the format of the RMP header. The notation used to represent the RMP header (shown in FIG. 7 as reference number 730) is the same notation used to document CML and CTP. This notation was introduced and described in the previous “Compact Data Structure Notation” section.

RMP Header: Bit lastDg // set for last datagram in a // message UIntV dgIndex // index of datagram

As shown, the RMP header 730 has only two fields: a single bit that is set for the last datagram of a message, and a variable size integer specifying the datagram index. The datagram index is zero for the first datagram in a message and increments by one for each subsequent datagram. The maximum allowed index for a datagram is 65534 (0.times.FFFE).

Notice that the RMP header 730 does not contain any fields specifying the packet length, the byte offset within the message that the packet represents, addressing information or port numbers. These fields are not required because RMP datagrams are sent using the Internet UDP protocol. The IP header 710 and UDP header 720 present in a UDP packet provide the overall packet length, source and destination machine addresses, and source and destination port numbers. As a further simplification, RMP ensures that datagrams are small enough to fit within a single network packet, so a single RMP datagram will never be fragmented across 2 or more IP packets. FIG. 7 illustrates an entire RMP Packet Structure 700.

The IP header 710 and the UDP header 720 are typically transmitted over the wireless network in a highly compressed form since most of the information in these headers is redundant or unnecessary over the wireless link. When using a packet data wireless network, the IP header 710 and UDP header 720 are reduced from 28 to 3 bytes. The “Wireless Network Interface” section below describes how the IP header 710 and UDP header 720 are compressed over the packet data wireless network.

The RMP Data Area

Because RMP packets are sent using UDP, and because UDP packets are always an even number of bytes long, the total size of the RMP area (header+data) is an even number of bytes long. Since the RMP header 730 is not generally an even number of bytes long, anywhere from 0 to 7 pad bits (which are always 0 bits) are appended to the header before the start of the data area in order to place the start of the data area on an even byte boundary.

The actual messages (e.g., message fragment 740) that RMP transports are an even number of bytes long. The box below illustrates the Data Area Padding and shows an example of a single packet request that has a 2 byte message in it. Notice that the header section is padded with 6 bits. This makes the entire RMP packet an integer number of bytes long (24 bits, or 3 bytes). If instead the RMP header 730 area had been 8, 16, or any other multiple of 8 bits long, then no padding bits would be inserted before the data area.

Bit Offset 0 Bit lastDG = 1 1 UintV dgIndex = 0 2 Bit[6] padding 8 Bit[16] data 24

Re-Transmission of Lost Packets

When RMP is being used over a network that does not guarantee delivery of packets, RMP provides a mechanism for the re-transmission of lost packets. Most reliable protocol designs rely on acknowledgements from the remote host to indicate to the sender that a packet was properly received. Then, if an acknowledgement is not received within a specified timeout period, the packet is resent. This method is not used in RMP because it forces a minimum of three packets to be exchanged for a single transaction (request to proxy server 180, response to wireless client 405, acknowledgement of response to proxy server 180).

Instead, RMP will assume by default that packets are correctly delivered to the remote host. The only time a packet will be re-transmitted is when an RMP re-transmit request is explicitly received from a remote host. Furthermore, the only time that a remote host will even send a re-transmit request is if the remote host has not received all packets from a multi-packet message within a certain timeout period.

Thus, for transactions with single packet requests and responses, packets will never be re-transmitted. If a response is not received within a certain timeout period, the reliable message layer 635 will simply return with a amount error and the user or higher layer software will have to re-submit the request. If at least one packet of a multi-packet message is received before the timeout period however, the reliable message layer 635 will send a re-transmit request to the remote host and tell it which datagrams of the message need to be re-transmitted. The following structure shows a re-transmit request:

Bit lastDg = 1 // always 1 UIntV dgIndex = 0xFFFF // special value indicates // re-transmit request UInt16 numSegments // number of segment pairs that // follow // First Segment UInt16 startDg0 // start datagram index UInt16 numDgs0 // number of datagrams in segment // Optional Additional segments . . . UInt16 startDg1 UInt16 numDgs1

The first two fields, lastDg and dgIndex are set to 1 and 0.times.FFFF respectively in order to identify this RMP packet as a re-transmit request. The numSegments field indicates how many startDg and numDgs pairs follow. Each startDg/numDg pair indicates a range of packets that need to be re-transmitted. For example, a startDg of 2 and numDg of 3 indicates that datagrams 2, 3 and 4 need to be re-transmitted. Finally, a numDgs value of 0.times.FFFF is a special case that indicates that all datagrams from startDg to the end of the message need to be re-transmitted. This special value is used because the host receiving the message does not know how big the entire message is until it receives the last packet in the message (the one with the lastDg bit set).

The definition of what range of bytes a particular datagram index represents is up to the sending host to decide and maintain. The receiving host simply tells the sender which datagrams have not been received by index, not by byte number or byte count.

This protocol, although very efficient in terms of network bandwidth, can place a significant burden on the sending host to implement, particularly the proxy server 180. For example, after a proxy server 180 sends a multi-packet response, the proxy server 180 saves the response data in a buffer somewhere just in case the wireless client 405 needs part of it re-transmitted. Only after the timeout period expires (which can be quite long for wireless networks—up to 60 seconds or more) can the proxy server 180 safely dispose of the response message and recover the memory used to hold it.

The Reliable Message Protocol

The reliable message protocol (RMP) protocol is described herein through examples. The RMP protocol combined with the compact transport protocol and the compressed markup language provide the basis for packet minimized communications between the wireless client 405 and the proxy server 180.

One embodiment of the invention includes a method for completing a transaction between the wireless client 405 and the proxy server 180. The method comprises transmitting a single request message from the wireless client 405 to the proxy server 180, and transmitting a single response message from the proxy server 180 to the wireless client 405. The request message comprises packets of data. Transmitting the request message comprises placing in the request message a base document uniform resource locator followed by compressed data. The compressed data comprises field values and field indices corresponding to fields in a hyperlink document, and an indication of use of a hyperlink document. Field values and field indices correspond to fields in the hyperlink document. The number of packets is small and the size of each packet is small.

In some embodiments, each response message packet is less than one kilobyte.

In some embodiments, the base uniform resource locator can be expressed in CTP by a binary string. The binary string includes a first field that indicates the encoding scheme used in the request message. The binary string can also include a second field comprising a representation of a second segment of the base uniform resource locator (URL). Lower case letters in the base URL and other selected text are represented by a multi-bit alphabet. The alphabet has less than eight bits. Characters not represented by the multi-bit alphabet, are preceded by a multi-bit escape character. The escape character indicates that text following the escape character is represented by a different scheme than the multi-bit alphabet. These alternate schemes can be eight bit ASCII representation or sixteen bit ASCII representation.

The simplest RMP case is where both the request and response messages are small enough to fit in one packet. As shown in FIG. 8, the wireless client 405 sends a single packet request 810 to the proxy server 180. Because the entire request fits in the one packet, the lastDg bit is set in the single packet request RMP header 850 to indicate that the single packet is the last packet in the request message. The single packet request 810 comprises an IP header 710, a UDP header 720, the single packet request RMP header 850, and a request message fragment (RQMF) 820.

The proxy server 180 then sends a single packet response 830 back to the wireless client 405 after processing the request. Because the entire response fits in one packet, the lastDg bit is set in the single packet response RMP header 860. The single packet response 830 comprises an IP header 710, a UDP header 720, the single packet response RMP header 860, and a response message fragment (RSMF) 840.

The RMP protocol is built on top of UDP. Each one of the examples that follow shows a complete transaction from the client's point of view. The wireless client 405 sends a single message request and receives a single message response. Whenever a wireless client 405 initiates a new transaction, the wireless client 405 uses the next available local UDP port number. This port number is sent to the proxy server 180 as part of the UDP header 720 information and tells the proxy server 180 to which port the response packets 830 are to be returned. By using a unique port number for each transaction, packets that do not belong to the current transaction can be safely and effectively ignored.

On the other hand, the destination port of each UDP transaction is constant for very transaction, i.e., the predefined port number for the UDP socket on the proxy server 180 that is listening for requests.

FIG. 9 shows an example of a seven hundred byte response message that is too large to fit in one five hundred byte packet. The proxy server 180 sends a two packet response back to the wireless client 405 where the first response packet 910 does not have the lastDg bit set in the first response packet RMP header 920. The second response packet 940 has the lastDg bit set in the second response packet RMP header 950. An interesting point to bring up here is that the RMP headers never indicate how many bytes of the message have already been sent, only the relative index of each packet. It is up to the receiver to determine the correct message byte offset of each packet by adding up the message fragment sizes from the previous packets.

FIG. 10 shows an example of a re-transmit packet being sent from the wireless client 405 to the proxy server 180. The proxy server 180 sends a two packet response back to the wireless client 405 but the second packet gets lost. The wireless client 405, after a timeout period, sends a re-transmit request 1010 back to the proxy server 180. Note that the numDgs field in the re-transmit request 1010 is 0.times.FFFF indicating that every datagram from the startDg to the end of the message is missing.

On Wireline Networks

When operating over a wireline network, the reliable message layer 635 uses the TCP Internet protocol instead of RMP to communicate with the proxy server 180. TCP provides acceptable performance over these networks because they have relatively low latency and high bandwidth. Performance issues aside, TCP is preferable over RMP because of its widespread use and implementation as an Internet standard.

The API to the reliable message layer 635 effectively hides the actual network and protocols used over the network Thus, the caller does not need to know whether RMP or TCP is being used to send messages to the remote host.

When TCP is being used on the wireless client 405, the reliable message layer 635 simply opens up a TCP connection to a pre-defined port number on the proxy server 180, and sends the actual message data. When the entire request message has been transmitted, the wireless client 405 shuts down the transmit side of the client's connection, causing the proxy server 180 to receive an end-of-file indication. This end-of-file indication informs the proxy server 180 that the request message as ended. Likewise, after the proxy server 180 sends the response back, it closes down the TCP connection and the wireless client 405 receives an end-of-file indication that the end of the response message has been transmitted.

Note that a new TCP connection is established for every transaction, i.e., a request message sent from wireless client 405 to proxy server 180 and a response message back from the proxy server 180. Whenever a new TCP connection is established on a host, a new unique local port number is assigned to the connection. This port number is used by TCP to keep track of connections—much like how RMP uses the UDP port number to keep track of its connections.

Reliable Message Layer Application Program Interface (API)

The reliable message layer 635 provides access to the remote host through the RMP or TCP protocols. When a wireline network is in place, the two hosts communicate using TCP, which is already built-in to nearly all desktop and server operating systems, as well as on the wireless communications device 100 operating system 102.

When a wireless network is in place, the two hosts communicate using the reliable message protocol. This protocol is unique to the wireless communications device 100 and therefore requires implementation on both the wireless client 405 and the proxy server 180. Rather than invent a whole new API however, the reliable message protocol will instead use the same Berkeley sockets API that's used for TCP and UDP. Berkeley sockets is the de-facto standard network API on most platforms.

Since both TCP and RMP are accessed through the Berkeley sockets API, there is very little layering that needs to be added on top of these two protocol APIs in order to provide a network independent reliable message layer 635 API. In fact, the only difference between the two protocols is the socket type used when opening up the socket (TCP vs. RMP). Hence, the only API call unique to the reliable message layer 635 on the wireless client 405 will be a call to return the preferred socket type to use when communicating over the wireless network. This call would query the list of network interfaces and return the correct socket type to use: SOCK_RDM (RMP) if there is a wireless network interface 510 available and the wireless communications device 100 antenna is up, or SOCK_STREAM (TCP) otherwise.

Using the Reliable Message Layer on the Wireless Communications Device

On the wireless communications device 100, the Reliable Message Protocol will be implemented as a new socket type to the network library. The network library is shown in FIG. 11 as 1110. The network library 1110 provides a Berkeley sockets API for network IO on the wireless communications device 100. The network library 1110 can support three socket types: datagram sockets, stream sockets, and message sockets. Datagram sockets utilize the UDP protocol, stream sockets utilize the TCP protocol, and message sockets utilize the RMP protocol.

Since RMP and TCP both use the Berkeley sockets API, the reliable message layer 635 API is essentially the Berkeley sockets API. Once a socket of the appropriate type has been opened, all other calls for reading and writing data, etc. are the same for the three protocols. There are certain usage restrictions in the sockets API that are observed (see below), but these restrictions can be applied equally to the socket types.

The following sequence of instructions details how the wireless client 405 application on the wireless communications device 100 performs a transaction with the proxy server 180. Keep in mind that every new transaction will go through the following sequence:

1.) Call RMLSocketType( ) to find out what type of socket to open up. This call will determine whether the client radio 440 antenna is up and if so, will return SOCK_RDM (Reliably Delivered Message) indicating that a RMP socket should be opened. If the client radio 440 antenna is not up, or if there is no wireless network interface 510 attached, SOCK_STREAM will be returned indicating that a TCP socket should be opened.

2.) Open up the socket using the socket( ) call. If there are any wireless network interfaces 510 attached, the socket( ) call will tell the wireless network interface 510 to prepare the client radio 440 for a transaction. Preparing the client radio 440 includes taking the client radio 440 out of low power mode, verifying signal strength, searching for a base station 170 if necessary, etc.

3.) Associate a local port number to the socket using bind( ) and a remote host IP address and port number using connect( ). The remote host port number used will be a pre-defined constant for the proxy server 180. The local host port number will be specified as 0—which tells the sockets API to pick the next unused local port number. Similar to sockets of type SOCK_DGRAM, SOCK_MESSAGE sockets do not perform any network IO during bind or connect calls. These calls simply store the local and remote addresses in the socket structure.

4.) Send the message request using write( ) send( ), sendto( ) or sendmsg( ). The entire message is passed at once (a requirement for SOCK_MESSAGE sockets) and the caller will not be allowed to send any more additional data for the same socket. After the message is sent, the socket should be shutdown in the transmit direction using shutdown( ) (a requirement for SOCK_STREAM sockets). The shutdown call is necessary so that the TCP socket on the proxy server 180 receives an end-of-file indication at the end of the message.

5.) Receive the response using read( ) recv( ) recvfrom( ) or recvmsg( ). These calls should be made repeatedly until end-of-file is returned, which indicates the end of the response message. Optionally, the caller can block on both network IO and user events simultaneously by using the select( ) call.

6.) Close the socket using close( ). If there are any wireless network interfaces 510 attached, this will have the side effect of putting the client radio 440 back into power-save mode.

Implementation of RMP

Ideally, RMP would appear as a new socket type on both the wireless communications device 100 and the proxy server 180 platform. Unfortunately, new socket types can not be easily implemented on the proxy server 180 since this is usually not a part of the proxy server 180 operating system that can be extended by third party developers. So, a compromise will be made on the proxy server 180 side. Therefore, the RMP protocol is implemented as a layer on top of the built-in sockets API, but with more or less the same calling conventions and parameters as the sockets API.

On the wireless communications device 100, the RMP protocol is incorporated into the network 1 library 1110 as a new socket type. In order to accomplish this, the network library 1110 is re-structured to allow for optional extensions, like RMP, that add new socket types or network types. This approach, although more involved than the approach taken on the proxy server 180 platform, paves the way for adding other socket types to network library 1110 in the future for features such as infra-red and non-IP network protocols.

Implementation of RMP on the Proxy Server

On the proxy server 180 platform, RMP will be implemented as a layer of code on top of a TCP (SOCK_STREAM) socket. This layer of code will have the same calling conventions as the standard sockets API and behave in the same manner. Each of the calls in this layer will have the name RMPxxxxx where xxxxx is the name of the corresponding sockets API call.

Nearly all of the RMP socket calls correspond to an equivalent sockets API call, except RMPReady( ) which is used to implement select( ) functionality. The select call is unique in that it provides blocking support for a set of different socket types at once—both RMP sockets and standard sockets. See the description below of SuperSelect( ) for details on how this functionality is implemented.

For convenience, RMP socket calls are written to simply fall through to the standard sockets call if the socket descriptor is not for a RMP socket. Similarly, the SuperSelect( ) call is written such that it can be used in place of the standard select( ) call.

RMPsocket

This call creates a new socket and returns the socket refnum. It will be implemented as follows:

If the family and type of the socket are not the right values for a RMP socket, simply call socket( ) and return.

Allocate a private structure to hold the RMP socket info.

Create a TCP socket and store its descriptor in the newly created RMP socket info structure.

Store the RMP socket structure pointer in a global array indexed by descriptor. This array is large enough to hold all possible descriptor values for the operating system since it is used by other RMP calls to determine if a given descriptor is for a RMP socket or a built-in socket. This global array is referred to as the descriptor array.

Return the TCP socket descriptor.

RMPlisten

This call prepares a socket to accept incoming connection requests. It will be implemented as follows:

Call listen( ).

RMPaccept

This call blocks until an incoming connection request arrives for the socket. It then creates a new socket for the connection and returns the new socket refnum. It will be implemented as follows:

Call accept( ).

RMPbind

This call specifies a local IP address and port number for the socket. It will be implemented as follows:

Call bind( ).

RMPconnect

This call specifies a remote IP address and port number for the socket.

Call connect( ).

RMPrecv

This call blocks incoming data from the remote host and returns the number of bytes read. If end-of-file has been reached (the remote host shutdown the transmit side of its connection), 0 is returned. It will be implemented as follows:

Lookup the associated RMP socket structure pointer from the global descriptor array. If this is not a RMP socket (nil RMP socket pointer), simply call recv( ) and return.

If the next 1 or more bytes of the message have already been queued up in the RMP socket structure, return them.

If no more data is queued up AND all parts of the message have already been received (including the last packet which has the lastDg bit set in the RMP header 730), return end-of-file (0).

Loop calling recv( ) on the TCP socket. If a packet arrives out of order, queue it up in the socket structure and keep looping. Otherwise, return the requested number of bytes from the packet.

RMPsend

This call sends data to the remote host. For RMP sockets, the entire message is passed at once to RMPSend. It will be implemented as follows:

Lookup the associated RMP socket structure pointer from the global descriptor array. If this is not a RMP socket (nil RMP socket pointer), simply call send( ) and return.

Split the message into chunks small enough to fit into single packets, add an RMP header 730, a UDP header 720, and an IP header 710 to each packet, and send the packets to the TCP socket using send( ). The lastDg bit is set in the RMP header 730 of the last packet. If the message is a multi-packet message, save it in the socket structure for a period of time (on the order of 60 seconds) in case the remote host later requests a re-transmission of some of the message. The re-transmit requests are watched for and handled by RMPclose.

Set flag in socket structure indicating that a message has been sent and that further RMPsend( ) calls to this socket are not allowed.

RMPshutdown

This call terminates further input and/or output on a socket. It will be implemented as follows:

Lookup the associated RMP socket structure pointer from the global descriptor array. If this is not a RMP socket (nil RMP socket pointer), simply call shutdown( ) and return.

Set flags in socket structure indicating that the socket has been shutdown and that further 10 in the receive and/or send direction is not allowed.

RMPclose

This call closes down a socket. It will be implemented as follows:

Lookup the associated RMP socket structure pointer from the global descriptor array. If this is not a RMP socket (nil RMP socket pointer), simply call close( ) and return.

Set flags in socket structure indicating that the socket has been shutdown and that further 10 in the receive and send direction is not allowed.

Set flag in socket structure indicating that the socket has been closed.

If there is no message data saved for possible re-transmission (sec RMPsend), free all memory allocated to the socket structure, close down the UDP socket, and remove the entry from the global descriptor array.

If there is message data saved for possible re-transmission, mark the socket structure as being in a close-wait state and block for a period of time (on the order of 60 seconds) waiting for re-transmit requests to arrive. If a re-transmit request is received during this time, re-transmit the requested packets (they were stored in the RMP socket structure pointer by RMPsend).

SuperSelect (int numfds, fd_set rfds, fd_set wfds, fd_set efds, struct timeval timeout)

This call is a replacement for the select( ) call. It supports RMP socket descriptors as well as standard descriptors. It blocks until any of the file descriptors in rfds, wfds, or efds become ready for 10 and updates rfds, wfds, and efds with the set of ready descriptors on exit.

SuperSelect is implemented using a subroutine call named RMPReady( ). RMPReady( ) takes a RMP socket descriptor parameter and a direction parameter. It returns 1 if the RMP socket is ready for 10 in the given direction, 0 otherwise. The direction parameter is either −1 for input, 0 for exception, or 1 for output.

Generally, the RMPReady( ) just loops calling select( ) on the TCP socket with a timeout of 0 until the socket either returns not ready, or until the next 1 or more bytes of message data can be queued up in the RMP socket structure. Each time that select( ) says that the TCP socket has a packet ready, the packet is read out of the TCP socket and queued into the appropriate place of the RMP socket structure. Since packets may arrive out of order, the arrival of a packet does not necessary mean that the RMPReady should return true.

The following pseudo-code illustrates how RMPReady( ) can be used to implement SuperSelect( ). In summary, SuperSelect first checks to see if at least one of the RMP descriptors are ready and if so, changes the timeout for the following select( ) call to 0. It then calls the select( ) call in order to update the list of standard descriptors that are ready for IO. Finally, it goes through each one of the RMP descriptors to see which RMP descriptors are ready. If no descriptors are ready at the end (which could happen if an out-of-order packet arrived at a RMP socket), it loops back to call select again.

int SuperSelect(int nfds, fd_set rfds, fd_set wfds, fd_set        efds, struct timeval timeout) { numReady=0 fd_set orig_rfds=rfds fd_set orig_wfds=wfds fd_set orig_efds-efds // // First, see if at least one of the RMP descriptors are ready // for each descriptor in rfds, wfds, efds if it is an RMP descriptor if timeout !=0 if RMPready(descriptor) timeout=0 // // If at least one of the RMP descriptors are ready, use a // 0 timeout just to update the list of other descriptors that  are // also ready. // while numReady=0 rfds=orig_rfds, wfds=orig_wfds, efds=orig_efds numReady=select(nfds, rfds, wfds, efds, timeout) // // Update the lists of standard descriptors that are ready  with // the RMP descriptors that are also ready. RMPReady is  smart // enough not to return true if the received packet is // out-of-order. // for each descriptor in rfds, wfds, efds if it is an RMP descriptor if not RMPReady(descriptor) rfds,wfds,efds[descriptor]=false numReady //end while return numReady }

Implementation of RMP on the Wireless Communications Device

On the wireless communications device 100, the RMP protocol is incorporated into the network library 1110 as a new socket type. Rather than statically link the RMP protocol into the network library 1110, the network library 1110 is re-structured to accept plug-in network library 1110 extensions that can add new socket or network types.

These network library 1110 plug-ins will be structured as wireless communications device 100 operating system 102 libraries, just like network library 1110 is a library, but with certain pre-defined entry points that are specifically for use by network library 1110. When the plug-in libraries are installed, they will register themselves with network library 1110 and tell network library 1110 which socket type(s) and network type(s) the plug-in libraries support.

Whenever network library 1110 receives a socket open request, it will check the network and socket type and call the appropriate network library 1110 plug-in library to handle the open request. In addition, any network library 1110 calls that take a socket refnum, like listen( ), accept( ), read( ), write( ), etc. will check the socket refnum and pass control onto the appropriate network library 1110 plug-in if the socket is not a built-in type.

The select( ) call in the Network library 1110 will also have to be extended in order to support Network library 1110 plug-ins. One embodiment of select for the Network library 1110 includes logic similar to that described above for the SuperSelect( ) call on the proxy server 180. It will have to be aware of plug-in socket types and call the appropriate plug-in library for any of the socket descriptors that don't correspond to built-in socket types. The plug-in library call will tell select whether or not that particular socket is ready for IO.

In order to simplify the allocation of socket descriptors, network library 1110 reserves a first group of socket descriptors for built-in socket types. Network library 1110 plug-ins can choose a free descriptor number from one of the other 12 possible descriptors that are not reserved for the built-in sockets (there are a total of 16 possible selectors on the wireless communications device 100). Having the descriptors partitioned in this way simplifies and speeds up the logic in the select( ) call and other portions of the network library 1110. Network library 1110 plug-in modules will also have to call the system event group signal function SysEvGroupSignal( ) whenever one of their sockets becomes ready for IO, just like built-in network library 1110 sockets do. This is done in order to unblock the select( ) call, and could be performed from an interrupt routine or a separate background task created by the plug-in.

An important thing to note about RMP sockets, is that the caller will call either recv or select repeatedly while waiting for a response to arrive. This is due to the way that re-transmit requests from the remote host are handled. Instead of creating a separate task to watch for re-transmit requests, the RMP plug-in simply looks for and processes re-transmit requests during recv and select calls.

Network Library RMP Socket Plug-in

The following descriptions provide a cursory overview of how each of the calls in the network library 1110 RMP socket plug-in will operate on the wireless communications device 100. An important difference this wireless client 405 implementation and proxy server 180 implementations of RMP is that the wireless client 405 side is implemented on top of UDP whereas the proxy server 180 is implemented on top of TCP. Since the following calls are part of the network library 1110 plug-in, they will be labeled as PIxxxxx where xxxxx is the particular sockets API call that each one implements.

PIsocket

This call creates a new socket and returns the socket refnum. It will be implemented as follows:

Allocate a private structure to hold the RMP socket info and grab an unused socket descriptor in the range allowed for Network library 1110 plug-ins.

Call Network library 1110 to create a UDP socket and store its descriptor in the newly created RMP socket info structure.

Return the RMP socket descriptor obtained in step #1.

PIlisten

This call prepares a socket to accept incoming connection requests. This call will not be implemented on the wireless client 405 since it does not support incoming RMP connection requests—only the proxy server 180 implementation does.

PIaccept

This call blocks until an incoming connection request arrives for the socket. It then creates a new socket for the connection and returns the new socket refnum.

This call will not be implemented on the wireless client 405 since it does not support incoming RMP connection requests—only the proxy server 180 implementation does.

PIbind

This call specifies a local IP address and port number for the socket. It will be implemented as follows:

Call the network library 1110 bind( ) call on the UDP socket descriptor.

PIconnect

This call specifies a remote IP address and port number for the socket. It will be implemented as follows:

Call the network library 1110 connect( ) call on the UDP socket descriptor.

PIsend, PIsendto, PIwrite, PIsendmsg

These calls send data to the remote host. For RMP sockets, the entire message is passed at once to RMPSend. They will be implemented as follows:

Get the pointer to the RMP socket info structure from the socket descriptor.

Split the message into chunks small enough to fit into single packets, add RMP headers 730, and send them to the UDP socket using send( ). The lastDg bit is set in the RMP header 730 of the last packet. If the message is a multi-packet message, save it in the socket structure in case the remote host later requests a re-transmission of some of the message. The PIrecv( ) and PIReady( ) calls will take the proper action and re-transmit request packets if they detect a re-transmit request while waiting for a response to arrive.

Set flag in RMP socket info structure indicating that a message has been sent and that further PIsend( ) calls to this socket are not allowed.

PIrecv, PIrecvfrom, PIrecvmsg, PIread

These calls block on incoming data from the remote host and return the number of bytes read. If end-of-file has been reached (the remote host shutdown the transmit side of its connection), 0 is returned. They will be implemented as follows:

Get the pointer to the RMP socket info structure from the socket descriptor.

If the next 1 or more bytes of the message have already been queued up in the RMP socket info structure, return them.

If no more data is queued up AND all parts of the message have already been received (including the last packet which has the lastDg bit set in the RMP header 730), return end-of-file (0).

Loop calling network library's 1110 recv( ) on the UDP socket. If a packet arrives out of order, queue it up in the RMP socket info structure and keep looping. If a re-transmit request packet is received, re-transmit the correct packets. Otherwise, return the requested number of bytes from the packet.

PIshutdown

This call terminates further input and/or output on a socket. It will be implemented as follows:

Set flags in socket structure indicating that the socket has been shutdown and that further IO in the receive and/or send direction is not allowed.

PIclose

This call closes down a socket. It will be implemented as follows:

Get the pointer to the RMP socket info structure from the socket descriptor.

Free the RMP socket info pointer.

Call the network library 1110 close( ) function on the UDP socket to close it down.

Network Library Select Call Enhancement

As mentioned above, the network library 1110 is enhanced to support plug-ins that provide new socket types and network types. Besides branching off to the correct plug-in handler for calls that operate on sockets (like bind, connect, send, recv, etc.) the network library 1110 is also plug-in aware in order to implement the select call.

Select (int numfds, fd_set rfds, fd_set wfds, fd_set efds, struct timeval timeout)

The select call blocks until any of the socket descriptors in rfds, wfds, or efds become ready for IO and updates rfds, wfds, and efds with the set of ready descriptors on exit.

Select is modified to look for sockets that belong to plug-ins and to utilize a routine in each plug-in named PIReady( ). PIReady( ) takes a socket descriptor parameter and a direction parameter. It returns 1 if the socket is ready for 10 in the given direction, 0 otherwise. The direction parameter is either −1 for input, 0 for exception, or 1 for output.

For RMP sockets, PIReady( ) just loops calling select( ) on the UDP socket that it owns with a timeout of 0 until the socket either returns not ready, or until the next 1 or more bytes of message data are queued up in the RMP socket structure. Each time that select( ) says that the UDP socket has a packet ready, the packet is read out and processed. Since packets may arrive out of order or they may be re-transmit request, the arrival of a packet does not necessary mean that the PIReady should return true.

The following pseudo-code illustrates how PIReady( ) will be used to implement select( ). In summary, it first checks to see if at least one of the plug-in descriptors are ready and if so, changes the timeout for the following select( ) call to 0. It then calls the select( ) call in order to update the list of built-in descriptors that are ready for IO. Finally, it goes through each one of the plug-in descriptors to see which plug-in descriptors are ready. If no descriptors are ready at the end (which could happen if an out-of-order packet arrived at a RMP socket), it loops back to call select again.

int select(int nfds, fd_set rfds, fd_set wfds, fd_set efds,          struct timeval timeout) { numReady=0 fd_set orig_rfds=rfds fd_set orig_wfds=wfds fd_set orig_efds=efds // // First, see if at least one of the plug-in descriptors are  ready // for each descriptor in rfds, wfds, efds if it is an plug-in descriptor if timeout !=0 if PIready(descriptor) timeout=0 // // If at least one of the plug-in descriptors are ready, use a // 0 timeout just to update the list of built-in descriptors that  are // also ready. // while numReady=0 rfds=orig_rfds, wfds=orig_wfds, efds=orig_efds numReady=select(nfds, rfds, wfds, efds, timeout) // // Update the lists of built-in descriptors that are ready with // the plug-in descriptors that are also ready. For example, // PIReady for RMP sockets is smart enough not to return  true // if the received packet is out-of-order. // for each descriptor in rfds, wfds, efds if it is an plug-in descriptor if not PIReady(descriptor) rfds,wfds,efds[descriptor]=false numReady //end while return numReady }

Wireless Network Interface

This section describes the wireless network interface 510 module for the wireless communications device 100 network library 1110. FIG. 11 shows a block diagram of the lower level communication layers on a wireless communications device 100. The wireless network interface 510 is seen situated between the network library 1110 and the network hardware 1120. The wireless network interface 510 isolates the actual network hardware 1120 from the network library 1110 and provides a generic interface to the network library 1110. The network library 1110 serves wireless client 405 applications 1130 and a client preference panel 1140.

This module enables the network library 1110 to access the Wireless packet data network as an IP network. Once installed, any application can access the Wireless packet data network using the Berkeley sockets API of the network library 1110.

The network library 1110 is designed in such a way that support for new network hardware, like the client radio 440, can be added dynamically simply by installing an appropriate network interface module onto the wireless communications device 100. Network interface modules are separately linked databases that contain the code necessary to abstract the network hardware. They can be “attached” and “detached” from the network library 1110 at run-time, usually through a preference panel 1140. For example, both PPP and SLIP are provided by separate network interface databases in the ROM and one or the other is selected for use through the network preference panel 1140.

In addition to the PPP and SLIP interfaces, wireless communication devices 100 also have a wireless network interface 510. When this wireless network interface 510 is attached to the network library 1110, applications will be able to communicate over the wireless packet data network using the Berkeley sockets API of the network library 1110.

The wireless communications system operates primarily through the proxy server 180 and therefore does not emphasize providing support for TCP/IP clients like FTP, Telnet, etc. that talk directly to standard Internet services. In particular, the wireless packet data network does not have the built-in IP routing support that would be necessary to transfer IP packets directly from a host on the Internet to a wireless client 405. Furthermore, wireless clients 405 do not have a unique Internet IP address assigned to them. However, there is a mechanism in place that allows wireless clients 405 to communicate indirectly with other hosts on the Internet 190, even in the absence of direct IP routing. In some embodiments, the wireless packet data network is enhanced to support direct IP routing without any further impact on the client software.

Structure of the Wireless Network Interface

Conceptually, all wireless network interfaces 510 have two entry points: a packet read/write entry point and a settings entry point. The packet read/write entry point is used e for sending and retrieving IP packets over the network. The settings entry point is used to configure the wireless network interface 510 with the appropriate settings it needs to communicate—such as IP address, user account information, etc. Typically, only a preference panel 1140 will change or access settings and only applications will read or write packets.

There are a number of existing pre-defined settings that are applicable across all wireless network interfaces 510; like IP address, subnet mask, etc. Besides providing a mechanism to configure the wireless network interface 510, the settings can also be read in order to query the wireless network interface 510 for information. Some of the currently defined settings are very general (like IP address) or applicable only to serial based interfaces (like login script, baud rate, etc.). If a particular setting is not applicable to a wireless network interface 510, the setting can be quietly ignored. For wireless network interfaces 510, like the wireless packet data network interface, a set of new settings is defined for wireless specific functionality. These new settings provide wireless network access point radio 420 specific information like signal strength, base station 170 info, etc.

Enhancements to the Network Library

A unique consideration of wireless network interfaces 510 is their power management. Unlike interfaces such as PPP and SLIP, it is very important that wireless network interfaces 510 are placed into power save mode whenever the wireless network interfaces 510 are not being used. In order to accomplish this, the network library 1110 is adapted to be wireless network “aware”, and hence able to place wireless network interfaces 510 into power-save mode when appropriate.

The network library 1110 generally takes the following course of action: when the first socket is opened, the network library 1110 tells all attached interfaces (through a new setting) to come out of power-save mode and to prepare for transactions; when the last socket is closed, the network library 1110 tells all attached interfaces to go back into power-save mode. This requires a change to the network library's 1110 socket open and close routines and a new setting that is implemented by all wireless network interfaces 510. Existing interfaces like SLIP and PPP can quietly ignore the new setting call. This model assumes that wireless applications will be conservative about opening sockets and immediately close them when no longer needed in order to save power.

Another consideration for wireless network interfaces 510 is that they generally search for a base station 170 when the wireless network interfaces 510 first power up. Typically, this search takes only a couple seconds. But if the user has traveled across country for instance, it could take ten seconds or more. This is not entirely unlike the connection negotiation sequence that PPP goes through when it starts up and can in fact be performed when the wireless network interface 510 is told to come “up” by the network library 1110—just like PPP and SLIP do. So, this feature of wireless network interfaces 510 does not require any new functionality on the part of the network library 1110.

Header Compression

Some embodiments of the invention include a method for formatting a packet of data. The formatting method comprises the following four steps. Determining that the packet destination is a proxy server 180. Setting a first bit in a compressed user datagram protocol (C-UDP) header to indicate that the packet destination is the proxy server 180. Placing bit flags in the C-UDP header to indicate whether optional delivery and Internet 190 protocol fields are included in the header. Placing a source port number identifying a wireless client 405 in the C-UDP header. The packet of data comprises a message encapsulated by the C-UDP header. In some embodiments, the bit flags indicate that no optional UDP fields and no optional Internet protocol fields are included in the C-UDP header.

In some embodiments, the method for formatting a packet of data further comprises the following steps are performed prior to determining that the packet of data is to be transmitted to the proxy server 180. A reliable message protocol socket splits messages received from wireless client 405 processing resources into datagrams. The reliable message protocol socket adds a reliable message protocol header 730 to the packet of data before passing the datagram to a user datagram socket. An Internet 190 protocol stack adds an Internet 190 protocol header 710 and a best effort delivery header to the packet of data before passing the packet of data to a wireless network interface 510. The packet of data comprises one of the datagrams.

In some embodiments, the method for formatting a packet of data further comprises the following two steps after placing a source port number in the C-UDP header identifying the wireless client 405 in the compressed C-UDP header after the plurality of bit flags. A wireless network interface 510 adding a wireless system header. Encapsulating the packet of data in the following order: the wireless system header followed by the C-UDP header, followed by the reliable message protocol header 730, followed by the message.

For some embodiments, wireless client 405 processing resources reside at a network library 1110 and comprise the reliable message protocol socket and the Internet protocol stack.

FIG. 12 shows a block diagram of wireless client 405 software and the s format of the data passed between each of the software layers. The application at the very highest layer sends messages to a reliable message protocol socket in the network library 1110. The reliable message protocol socket then splits the message into datagrams and adds a RMP header 730 to each datagram before passing it to a UDP socket of the network library 1110. The IP stack in the network library 1110 then adds an IP header 710 and UDP header 720 to each packet and passes the packets on down to the wireless network interface 510.

As shown in FIG. 12, packets that get sent to the packet-write entry point of the wireless network interface 510 by the network library 1110 have an IP header 710, followed by a UDP header 720, followed by a RMP header 730, and finally, the message datagram.

Now, before the wireless network interface 510 passes the packet to the client radio 440, the wireless network interface 510 adds the wireless network protocol header, called a WLNP, to the packet. A WLNP header contains source and destination host addresses and the overall packet size, among other things. All hosts on the wireless packet data network are addressed using unique source account numbers that are 24 bits long.

In the case where the packets are destined for the proxy server 180, the unique destination account number will be of the tunneler 430, which can be connected through an X.25 link to a wireless network access point 410 as illustrated in FIG. 5—Wireless Network Topology. The unique source account number will be the client's unique account number. Since the source and destination host addresses are already specified in the WLNP header, the source and destination IP addresses that are in the IP header 710 are not necessary.

In addition to source and destination IP addresses, there are a number of other fields in the IP header 710 and the UDP header 720 that are not required when transferring RMP datagrams between the wireless client 405 and the proxy server 180. In order to reduce the overall header size to an absolute minimum, the entire IP header 710 and UDP header 720 are replaced with a Compressed UDP (C-UDP) header which contains only the bare minimum amount of information necessary. Likewise, at the proxy server 180 side, the tunneler 430 will have to re-create the original IP header 710 and UDP header 720 using just the information from the WLNP and C-UDP headers.

The C-UDP Header

In order to determine what information is necessary in the C-UDP header, we look at a number of factors, including the contents of IP header 710 and the UDP header 720 as well as the environment in which the C-UDP headers are used. Unlike the IP header 710 and the UDP header 720, the C-UDP header is not optimized as a general purpose header. The C-UDP header can be highly specialized (and hence highly compressed) for use between a wireless client 405 and proxy server 180 over the wireless packet data network. The C-UDP header also provides a mechanism to represent any possible IP packet type that could be sent from a wireless packet data network wireless client 405 including IP packets meant for applications other than a wireless communications device 100.

FIG. 13 shows the format of the IP header 710 and the UDP header 720. All together, the two headers take up 28 bytes: 20 for the IP header 710 and 8 for the UDP header 720.

The format of the C-UDP header using the notation used to document CML and CTP is shown below. This notation was introduced and described in “Compact Data Structure Notation” section above.

Bit jerryPkt Bit has VersHlenServiceTTL Bit hasFragmentation Bit hasProtocol Bit hasSrcIP Bit hasDstIP Bit unused Bit noCompression // see description. if OerryPkt) Bit[16] sourcePort // UDP source port else if (hasVersHlenServiceTML) Bit[4] vers Bit[4] hlen Bit[8] serviceType Bit[8] ttl if (hasFragmentation) Bit[16] identification Bit[3] fragFlags Bit[13] fragOffset if (hasProtocol) Bit[8] protocol if (hasSrcIP) Bit[32] sourceIPAddr if (hasDstIP) Bit[32] destIPAddr if (hasVersHlenService) UInt32[?] ipoptions if (!hasProtocol 11 protocol=udp) Bit[16] sourcePort Bit[16] destPort /IByte[ ] udpData else //Byte[ ] ipData /may include TCP header

The C-UDP header can compress any type of IP protocol, not just the UDP protocol like the name implies. It is optimized however for UDP and doesn't provide as optimal a level of compression for other protocols like TCP.

The C-UDP header has a number of optional fields that are either present or not, depending on the value of the flag bits in the beginning of the header. The following subsections explain the various formats of the C-UDP header and where they are used.

The C-UDP Header for Compressed Packets

The first bit in the header is set for packets sent using the UDP protocol to the proxy server 180. For these packets, the only fields present in the C-UDP header are the UDP source port number for the wireless client 405 and the other seven bit flags for optional UDP header 720 and IP header 710 fields as shown above. The RMP header 730 and data then immediately follow the UDP source port number. All other fields that are present in normal IP header 710 and UDP header 720 can be omitted.

The vers, hlen, and serviceType fields can be omitted because these packets use version 4 of the IP header 710, have no IP options, and use normal service type. The total length is redundant because the WLNP header contains the total length. The identification, fflags, and fragment offset fields can be omitted because RMP datagrams are guaranteed to be small enough to not require fragmentation. The time to live field is not required because these packets go directly to the proxy server 180 at the wireless network access point 410 and do not pass through any IP routers. The protocol field is not required because the protocol is always UDP. The header checksum is not required because WLNPs already have CRC checks for data integrity. The source and destination IP addresses are not required because the source and destination hosts can be identified by the source and unique destination account numbers in the WLNP header.

Regarding fields in the UDP header 720, the UDP dest port is not required since the packets are always destined for the proxy server 180 destination port and the UDP message length and checksum are not required because the WLNP header already contains the overall packet length and has a CRC check for data integrity.

The wireless network interface 510 can determine if a packet can be compressed into this format by checking that the destination IP address is for the proxy server 180, that the protocol is UDP, and that the destination UDP port number is for the proxy server 180 service port. Determining that the destination IP address is for the proxy server 180 can be done by checking for a special value or comparing it with a value that has been registered with the wireless network interface 510 through a settings call. Since the packet itself will not go out onto the Internet 190, the address used to identify the proxy server 180 does not have to be a unique Internet IP address.

The C-UDP Header for Generic UDP Packets

For UDP packets that are not destined for the proxy server 180 service port, the first bit in the packet header will be 0 and will be followed by 7 more bits of flags that indicate the presence of other optional IP header 710 and UDP header 720 fields.

If the packet has a vers field of 4, no IP options, and a standard service type field (0), then the hasVersHlenService bit will be 0. Otherwise, the vers, hlen, and serviceType fields will follow the 8 bits of flags.

If the packet is not fragmented (the more fragments bit in the fFlags field is clear and the fragment offset is 0), then the hasFragmentation bit will be 0. Otherwise, the identification, fFlags, and fragment offset will be included. Notice the only time the identification field is present is when the fragmentation fields are also included. Technically, this identification field is not required except for fragmented packets, but there is a possibility that some IP implementations may not work correctly if this field is not sent verbatim between the 2 hosts.

If the packet's ttl field is the default ([what is the default value??]), then the hasTTLProtocol bit will be 0. Otherwise, the ttl and protocol (which is UDP) fields will be included.

If the source IP address is included in the packet, then the hasSrcIP bit will be set. Whether the source IP address is included or not is up to the wireless network interface 510 to decide. In some embodiments, the rule applied is to only include the source IP address if in fact the wireless client 405 has a real Internet 190 or intranet IP address. There is also a setting for wireless network interfaces 510 that gets set by a preference panel 1140 and this new setting will tell the wireless network interface 510 whether or not the wireless client 405 owns a genuine IP address or just a fake placeholder.

If the destination IP address is included in the packet, then the hasDstIP bit will be set. The only time the destination IP address will be left out is when sending packets to the proxy server 180.

The C-UDP Header for Other IP Packets

If a packet is not a UDP packet, its compressed format will generally be the same as for generic UDP packets described above, but the hasTTLProtocol bit will be set, the ttl and protocol fields will be included, and the sourcePort and destPort fields will NOT be included. Instead, the protocol specific fields will appear as-is immediately following the C-UDP header. For example, a TCP packet that has a destination IP address but no IP options would have its IP header 710 portion compressed into the C-UDP header format but its TCP header fields would appear as-is immediately after the destIPAddr field in the C-UDP header.

Finally, yet another option for C-UDP headers is for the noCompression bit to be set. If this bit is set, there are NO other fields from the C-UDP header following the first 8 bits of flags. Instead, the original, unadulterated IP header 710 and data of the packet will immediately follow the 8 bits of flags.

Proxy Server Details

Many embodiments of the invention arise from combining the compression techniques discussed above with proxy server 180 processing resources and wireless client 405 processing resources. Some of these embodiments are discussed directly below.

Some embodiments of the proxy server 180 include a method of transforming a first CTP message into an HTML request. In some embodiments, the method of transforming comprises combining the first message received from the wireless client 405 with a hypertext markup language hyperlink document. The first message comprises compressed representations of field values and field indices corresponding to fields in the hypertext markup language hyperlink document.

The proxy server 180 responds to requests by wireless clients 405 to fetch either web content or messaging information. The proxy server 180 carries most of the burden of bringing the information from the Internet 190, converting it to wireless client 405 compatible CTP and CML formats, and transferring it to the wireless client 405 over the wireless network. The wireless client 405, by comparison, simply sends requests to the proxy server 180 and displays the transferred data onto the wireless communications device 100 screen 101.

The proxy server 180 adequately services 100,000 users without introducing substantial delays. The proxy server 180 design is scalable so that any number of users can be supported in the future.

Besides acting as a proxy server 180 to the wireless clients 405, the proxy server 180 also acts as a client to existing Internet 190 mail and web servers. This means that the proxy server 180 includes support for almost all versions of HTML, HTTP, SMTP, POP, etc. as well as support for security protocols like SSL, S-HTTP, etc.

As described herein, some wireless network layouts require the use of multiple proxy servers 180 scattered throughout different regions in order to adequately service the entire country. Thus, proxy server 180 is designed to run on multiple machines simultaneously.

The proxy server 180 is to be stateless. In general, a stateless design is more tolerant of communication and protocol errors than a stateful design. A stateless design is also easier to implement and manage, especially with a network of distributed proxy servers 180. For example, with multiple distributed proxy servers 180, a stateful design would have to transfer state from one proxy server 180 to another if a user happened to temporarily move to a different region or if one of the proxy servers 180 went down for maintenance.

Because the proxy server 180 connections are distributed throughout various regions, proxy server 180 processing resources are replicated onto as many machines as necessary in order to handle regional loads. Proxy server 180 processing resources are shared on two or more machines to for load sharing for a single region and to provide both load balancing and continuous service in case a single machine goes down.

The proxy server 180 design is stateless so that the proxy servers 180 do not have to share information with each other, and so that users will not encounter any difficulties when they move from area to area and change which proxy server 180 they are using.

Some embodiments of the proxy server 180 can support a user database. The user database sets browsing options, messaging options, etc. on the proxy server 180 and reduces the amount of data that is sent between the wireless client 405 and proxy server 180 during normal operation. The user database is also used to collect statistics on usage patterns. Note that the user database is shared between all the proxy servers 180.

The proxy server 180 design also enables corporations to create their own intranets. For example, corporations can use a leased line connection from the nearest wireless network access point 410 center to a proxy server 180 at the corporation's own site and connected to the corporation's private intranet. To facilitate this, proxy server 180 processing resources are easy to setup, maintain and operate using off-the-shelf hardware.

The performance goal of the proxy server 180 is to process each request in less than 1 second. That is, given a typical request of 40 bytes to the proxy server 180, the proxy server 180 is able to access the requested content off the Internet, reformat it, and send a typical size response of 360 bytes to the wireless client 405 in less then one second. Taking into account the bandwidth and latency of the wireless packet data network, the user will see roughly a 7 to 11 second response time overall. The peak usage rate of the wireless communications devices 100 with 100,000 users will be 920,000 transactions per hour which is 256 transactions per second. This load can be divided up by as many proxy servers 180 as required.

Another important component of the proxy server 180 design is configuration and trouble-shooting support. Configuration support includes mechanisms for configuring the proxy server 180 for different environments, adjusting performance settings, displaying usage statistics, etc. These are all tasks that a system administrator performs when first setting up the proxy servers 180 and also performs periodically in order to keep the proxy servers 180 tuned and to monitor their performance. Trouble-shooting support includes mechanisms for an engineer to debug problems with the design and to enable special purpose diagnostics. Because of the distributed nature of the proxy server 180, these functions are controlled remotely. In order to enable remote control, the proxy server 180 processing resources support a telnet-like connection for these purposes.

Communications System Details

Many embodiments of the invention arise from combining the compression techniques discussed above with proxy server 180 processing resources, wireless client 405 processing resources, and features of the wireless packet data network. Some of these embodiments are discussed directly below.

Some embodiments of the invention provide a wireless client 405 comprising means for requesting a hyperlink document in a compressed form. The means for requesting a hyperlink document in a compressed form comprise means for sending a base document uniform resource locator followed by a compact representation of a first hyperlink and a compact representation of a hash value corresponding to the first hyperlink to proxy server 180 processing resources.

In some embodiments the wireless client 405 further comprises means for completing a transaction between a wireless client 405 and a proxy server 180. Some embodiments of the wireless client 405 further comprise means for transmitting a first message in packets of data to a proxy server 180. The first message corresponds to a hypertext document. The hypertext document has input fields and control fields. The means for transmitting comprises the following two steps. Submitting compressed representations of data corresponding to input fields and control fields formatted according to CTP to wireless client 405 processing resources. Transmitting packets of data comprising compressed representations of data to the proxy server 180. The compressed representations comprise text and name attributes corresponding to input fields and compressed values and value attributes corresponding to control fields and select fields.

In some embodiments of the wireless client 405 means for completing a transaction between a wireless client 405 and a proxy server 180 comprise means for transmitting a single request message sent from the wireless client 405 to a proxy server 180 and means for receiving a single response message from the proxy server 180. The request message comprises packets of data. Means for transmitting the request message comprise means for placing in the request message a base uniform resource locator followed by compressed data. The compressed data comprise field values and field indices corresponding to fields in a hyperlink document, and an indication of use of a hyperlink document.

Some embodiments of the invention include communications system comprising a source of data, a wireless client 405, and a proxy server 180. The wireless client 405 comprises means for requesting a hyperlink document in a compressed form. The proxy server 180 comprises means for transforming a first message into an HTML request, and means for converting an HTML response into a second message in a compact markup language. Some embodiments of the communications system further comprise a wireless network. The wireless network is in communication with both the proxy server 180 and the wireless client 405. For some embodiments of the communications system, the proxy server 180, the wireless client 405, and the source of data are disposed at three separate locations. For some embodiments of the communications system, the compact markup language comprises a stream of data comprising text and image data. The text data comprises multibit character representations for selected characters, eight-bit character representations for a first set of unselected characters, and sixteen-bit character representations for a second set of unselected characters, the multi-bit character representations comprising less than eight bits.

Some embodiments of the communications system further comprise means for completing a transaction between a wireless client 405 and a proxy server 180. The means for completing the transaction comprise means for transmitting a single request message from the wireless client 405 to the proxy server 180 and means for transmitting a single response message from the proxy server 180 to the wireless client 405. The request message comprises packets of data. Transmitting the request message comprises placing in the request message a base uniform resource locator followed by compressed data. The compressed data comprises field values and field indices corresponding to fields in a hyperlink document, and an indication of use of a hyperlink document. The single response message comprises packets of data. For some embodiments of the communications system, the number of packets in the request message is one and the packet size is less than one kilobyte.

Tunneling Support

Because the proxy server 180 is connected to the wireless network access point 410, the proxy server 180 can communicate with wireless clients 405 without having to go over the Internet 190. Therefore, the proxy server 180 does not require the IP routing support that other hosts on the Internet 190 would require. Generic IP access between wireless clients 405 and other hosts on the Internet 190 can be accomplished by adding the appropriate IP routing support to the wireless network access point 410 and assigning a unique Internet IP address to each wireless client 405.

As an alternative to direct IP routing support over the wireless packet data network, the proxy server 180 tunneler 430 (which can be a part of the proxy server 180 processing resources) will support a mechanism that enables wireless client 405 applications to “tunnel” IP packets to and from other hosts on the Internet 190. But, because the IP packets are imbedded within a TCP stream, custom proxy server 180 software written on the remote host is required in order to accept, process, and reply to these tunneled packets.

FIG. 5, Wireless Network Topology, shows a diagram of how the wireless client 405, wireless network, and tunneler 430 are interconnected. In general, the tunneler 430 takes packets off the wireless network, restores the original IP header 710 and UDP header 720 from the WLNP and C-UDP headers, and then tunnels each packet to the appropriate host using TCP. Most of the packets off the wireless network will be destined for the proxy server 180, but the packets can be sent to any other host accessible from the tunneler 430 over TCP. The tunneler 430 simply uses the destination IP address of each packet to determine which host is to receive the packet.

For a wireless packet data network with IP routing support, the tunneler 430 can act as a gateway and send the packets directly to the remote host without tunneling them within a TCP stream. Then, because the Internet 190 routing support would be in place, the packets sent back from the remote host would find their way back to the tunneler 430 and then get forwarded back over the wireless network to the wireless client 405.

With IP routing support present on the wireless packet data network, the tunneler 430 decides whether to send packets within a TCP stream to the remote host or to send them directly. There are advantages to tunneling packets even when IP routing support is available because the wireless client 405 can use the more efficient UDP protocol over the wireless link but still be guaranteed that the UDP packets received by the wireless access point 410 get delivered to the Internet 190 host (since they are sent using TCP). In order to make this decision easy for the tunneler 430, the following rule is used: the tunneler 430 will only tunnel UDP packets that have a destination UDP port number of between 0.times.7000 and 0.times.7FFF.

In order to effectively use the tunneler 430, the wireless client 405 and the proxy server 180 processing resources follow similar rules as those used by the RMP protocol. Namely, the host on the Internet 190 automatically closes down the TCP connection between it and the tunneler 430 whenever a transaction is over. Otherwise, TCP connections established from the tunneler 430 to remote hosts would remain open indefinitely. Just in case though, the tunneler 430 has a fairly large inactivity timeout on the TCP connections in order to automatically close them down.

Alternative System

FIG. 14 illustrates another embodiment of a system that allows the wireless communications device 100 to communicate with the web server 140.

The system of FIG. 14 illustrates an alternative embodiment where users can turn their own desktop computers or servers into wireless communications base stations 170 and proxy servers 180 for communicating with their wireless communications devices 100. The users install transceiver cards, or other hardware, and software on their computers. In this way, users can provide localized “free” Internet 190 access to wireless communications devices 100. Corporations can purchase additional hardware and software for some user computers or servers throughout their campus. Thus, the corporations can provide wireless communications to their employees. Alternatively, standalone systems can be purchased and plugged directly into the corporate Intranet.

The following describes an embodiment of the invention where a user's computer is substituted for the base station 170 and the proxy server 180. The other embodiments of the invention work in a similar manner.

Instead of the base station 170 and the proxy server 180, a user computer 1482 is included in this system. The user computer 1482 is executing a wireless and Internet communications program 1486. The user computer 1482 also includes an antenna 1470 and related wireless communications hardware. The user computer 1482 has an Internet connection that can be used for communicating to the web server 140.

The wireless communications device 100 communicates wirelessly with the user computer 1482. In one embodiment of the invention, the protocols used to communicate wirelessly are the same as those used in the wireless packet data network described above. In one embodiment of the invention, the wireless communications device 100 can communicate with both the wireless packet data network and computers having the wireless communications capability of the user computer 1482. However, other communications protocols can be used instead.

The wireless and Internet communications program 1486 performs the functions of the base station 170 and the proxy server 180.

In some embodiments, the user computer 1482 couples to a proxy server 180 through the Internet 190. The wireless and Internet communications program 1486 provides wireline communications to the proxy server 180. This would be for the purposes of providing secure communications, e-mail access, or for updating query form information that is not stored in the user computer 1482. In this configuration, the wireless and Internet communications program 1486 can perform the basic wireless communications base station functions, while the proxy server 180 can still perform the security and other proxy server functions. This configuration helps to provide users with a higher degree of security because the proxy server 180 is performing the secure communications with the web server 140. The proxy server 180 or the user computer 1482 can perform the conversions.

In some embodiments, instead of a transceiver card, an external transceiver device is used. The external transceiver can be connected to the computer via, for example, a serial connection, a Universal Serial Bus, a SCSI connection, or some other connection.

In some embodiments, the device is a standalone device that couples directly to a network (e.g., the device has its own IP address).

In some embodiments of the invention, the wireless communications device 100 can communicate with both the Mobilex system, or some other wireless data communications system, and the wireless communications system established with the computer 1482. 

What is claimed is:
 1. A handheld computer comprising: a display; an antenna; a local memory configured to store sets of predefined data comprising executable wireless applications, each wireless application representing a static portion of a different website; and a processor configured to: present on said display service icons corresponding to said wireless applications; in response to user activation of a displayed icon, execute the corresponding wireless application stored in local memory; render a query form stored in local memory for the selected website associated with that wireless application; generate a query based on user-input to the query form; send a wireless communication over the antenna for the selected website, the wireless communication comprising the query with the user-input; receive a response over the antenna, the response representing dynamic data originating from the selected website; and present one or more pages on the display comprising static data derived from the set of predefined data for the selected website and dynamic data derived from the response received over the antenna from the selected website.
 2. The handheld computer of claim 1, wherein the wireless communication is signaled from the antenna in a compressed markup language.
 3. The handheld computer of claim 2, wherein the compressed markup language corresponds to Compact Markup Language (CML).
 4. The handheld computer of claim 1, wherein the one or more pages are linked to one another, and wherein at least some of the data for linking the one or more pages to one another is stored with the set of predefined data configured for the selected network site.
 5. The handheld computer of claim 1, wherein the response originating from the website is received from the website in a compressed markup language.
 6. The handheld computer of claim 1, wherein the processor is further configured to execute an application associated with the selected website, the application accessing the set of predefined data to generate the form for the selected website.
 7. The handheld computer of claim 6, wherein the application associates a plurality of network pages configured for the selected website.
 8. The handheld computer of claim 1, further comprising a serial port to exchange communications with another computer, and wherein the set of predefined data for the selected website is signaled from another computer over the serial port.
 9. A method comprising: storing sets of predefined data comprising executable wireless applications, each wireless application representing a static portion of a different website, in a memory of a handheld computer; presenting on a display of the handheld computer service icons corresponding to said wireless applications; in response to user activation of a displayed icon, executing the corresponding wireless application stored in local memory; rendering a query form stored in local memory for the selected website associated with that wireless application; generating a query based on the user-input to the query form; sending a wireless communication over an antenna of the handheld computer for the selected website, the wireless communication comprising the query; receiving a response over the antenna, the response originating from the selected website; and presenting one or more pages on the display of the handheld computer comprising static data derived from the set of predefined data for the selected website and dynamic data derived from the response received over the antenna from the selected website.
 10. The method of claim 9, wherein the wireless communication is signaled from the antenna in a compressed markup language.
 11. The method of claim 10, wherein the compressed markup language corresponds to Compact Markup Language (CML).
 12. The method of claim 11, wherein the one or more pages are linked to one another, and wherein at least some of the data for linking the one or more pages to one another is stored with the set of predefined data configured for the selected website.
 13. The method of claim 9, wherein the response originating from the website is received from the network site in a compressed markup language.
 14. The method of claim 9, further comprising: executing an application associated with the selected website, the application accessing the set of predefined data to generate the query form for the selected website.
 15. The method of claim 14, wherein the application associates a plurality of network pages configured for the selected website.
 16. The method of claim 9, wherein the set of predefined data for the selected website is signaled from another computer over a serial port of the handheld computer. 